Abstract 4146302: NETosis Attenuating Nanoprobe Improves Survival after Cardiac Arrest

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NETosis, the process of neutrophil cell death due to the formation and release of neutrophil extracellular traps (NETs) has been implicated in the pathogenesis of heart disease. NETs are composed of immunogenic DNA fragments and citrullinated histones. The role of NETosis in the context of cardiac arrest and resuscitation (CA/R) is however unknown. We previously reported the development of a Dextran-Thiazole Orange (DTO) nanoprobe, with nanomolar affinity for nucleic acids, that exerts acute anti-inflammatory effects and reduces ischemia-reperfusion injury in mice. We aimed here to determine whether the DTO nanoprobe would also bind to the nucleic acid in NETS, whether DTO could attenuate the intensity of NETosis, and whether this would improve outcomes and survival after cardiac arrest. C57Bl6 mice were arrested for 8 minutes before resuscitation. DTO or unmodified dextran (vehicle control) was injected at the time of resuscitation, and again 4 hours later (n=38 mice). Survival and neurological function were scored daily. Time-domain resolved (lifetime) and conventional fluorescence imaging was performed at 4 hours after resuscitation in 6 additional mice injected with DTO. NETosis was evaluated by protein blot in the hearts of cardiac arrest mice injected with DTO or control. DTO significantly (p<0.05) improved 10-day survival (Fig. A), mean survival (from 4 to 7 days, Fig. B), and neurological function (Fig. C) following CA/R. Lifetime imaging (Fig. D), but not conventional fluorescence imaging (Fig. E) revealed the presence of DTO in the injured heart, liver and kidneys. In the heart, DTO signal was significantly increased in CA/R compared to sham mice injected with DTO or CA/R mice injected with control dextran (Fig. F). Citrullinated H3 and HMGB-1 (High mobility group box 1, a chromatin protein) were both upregulated in CA/R, and were significantly attenuated by DTO injection (Fig. G-I). We show for the first time that NETosis plays a key role in cardiac arrest and resuscitation. DTO is capable of detecting NETosis as well as attenuating it, likely via a reduction in HMGB-1 activity. The modulation of NETosis may provide a new avenue to improve survival after cardiac arrest.