Intravenous multipotent adult progenitor cell therapy after traumatic brain injury: Modulation of the resident microglia population

Introduction: we have demonstrated previously that the intravenous delivery of multipotent adult progenitor cells (mapc) after traumatic brain injury affords neuroprotection via interaction with splenocytes,leading to an increase in systemic anti-inflammatory cytokines. we hypothesize that the observed modulation of the systemic inflammatory milieu is related to t regulatory cells and a subsequent increase in the locoregional neuroprotective m2 macrophage population.methods: c57b6 mice were injected with intravenous mapc 2 and 24 hours after controlled cortical impact injury. animals were euthanized 24,48,72,and 120 hours after injury. in vivo,the proportion of cd4+/cd25+/foxp3+ t-regulatory cells were measured in the splenocyte population and plasma. in addition,the brain cd86+ m1 and cd206+ m2 macrophage populations were quantified. a series of in vitro co-cultures were completed to investigate the need for direct mapc:splenocyte contact as well as the effect of mapc therapy on m1 and m2 macrophage subtype apoptosis and proliferation.results: significant increases in the splenocyte and plasma t regulatory cell populations were observed with mapc therapy at 24 and 48 hours,respectively. in addition,mapc therapy was associated with an increase in the brain m2/m1 macrophage ratio at 24,48 and 120 hours after cortical injury. in vitro cultures of activated microglia with supernatant derived from mapc:splenocyte co-cultures also demonstrated an increase in the m2/m1 ratio. the observed changes were secondary to an increase in m1 macrophage apoptosis.conclusions: the data show that the intravenous delivery of mapc after cortical injury results in increases in t regulatory cells in splenocytes and plasma with a concordant increase in the locoregional m2/m1 macrophage ratio. direct contact between the mapc and splenocytes is required to modulate activated microglia,adding further evidence to the central role of the spleen in mapc-mediated neuroprotection. © 2012 walker et al.; licensee biomed central ltd.