Abstract Body (Do not enter title and authors here): Introduction: Intracranial aneurysms are associated with local degradation of the vessel wall resulting in the formation of a blood-filled sac. Approximately 6 million people are estimated to have intercranial saccular aneurysms in the US alone. Most aneurysms remain undetected until rupture, resulting in hemorrhage which carries a high mortality rate (>50%). Flow diverters are placed across the aneurysm neck to divert blood flow away from the sac, preventing rupture once occluded. However, flow diverters carry significant risk for thromboembolism, which is a major cause of morbidity. The elevated risk of thromboembolism is likely due to endothelial injury of the parent artery at the neck of the aneurysm. We hypothesize that the bionanomatrix can promote faster endothelialization and aneurysm occlusion thereby reducing the risk of thromboembolism after flow diverter treatment.
Methods: The bionanomatrix is composed of peptide amphiphiles containing endothelial cell adhesive ligand (YIGSR) and a nitric oxide (NO) donor (KKKKK), both components critical for recruiting and retaining endothelial cells on the device. The NO releasing bionanomatrix was coated onto the flow diverters using ultrasonic spray coating, and the NO effects on endothelial cell (EC) and smooth muscle cell (SMC) proliferation on the coated devices was assessed, in vitro, using calcien-AM staining. For the in vivo study, an elastase-induced rabbit aneurysm model was created. The bionanomatrix coated and uncoated flow diverters were implanted into the rabbit aneurysm model for 4 weeks. The coated and uncoated flow diverters were then analyzed for endothelialization, smooth muscle cell proliferation, and aneurysm occlusion by angiography, gross image, and immunohistochemistry analyses.
Results: In vitro, the bionanomatrix coated flow diverters significantly enhanced endothelial cell proliferation as well as reduced smooth muscle cell proliferation on the flow diverters compared to the uncoated device. In vivo, after 4 weeks, the bionanomatrix coated flow diverters demonstrated enhanced neck coverage, more complete endothelialization, and reduced smooth muscle thickness on the coated flow diverters compared to the uncoated devices as seen by gross image analysis and histology.
Conclusions: The bionanomatrix coated flow diverters can successfully promote faster endothelialization and brain aneurysm occlusion which is critical for reducing the risk of thromboembolism after neurointervention.