McNally Melanie A, Lau Lauren A, Granak Simon, Hike David, Liu Xiaochen, Yu Xin, Donahue Rachel A, Chibnik Lori B, Ortiz John V, Che Alicia, Northington Frances, Staley Kevin
bioRxiv. 2024 Dec 20:2024.12.19.629457. doi: 10.1101/2024.12.19.629457.
Mild hypoxic-ischemic encephalopathy is common in neonates with no evidence-based therapies, and 30-40% of patients experience adverse outcomes. The nature and progression of mild injury is poorly understood. Thus, we studied the evolution of mild perinatal brain injury using longitudinal two-photon imaging of transgenic fluorescent proteins as a novel readout of neuronal viability and activity at cellular resolution. In vitro, perinatal murine organotypic hippocampal cultures underwent 15-20 minutes of oxygen-glucose deprivation. In vivo, mild hypoxia-ischemia was completed in post-natal day 10 mouse pups of both sexes with carotid ligation and 15 minutes of hypoxia. Consistent with a mild injury, minimal immediate neuronal death was seen and there was no volumetric evidence of injury by ex vivo MRI 2.5 weeks after injury. In both the hippocampus and neocortex, these mild injuries resulted in a significantly delayed and progressive neuronal loss in the second week after injury, measured by fluorophore quenching. Mild hypoxia-ischemia transiently suppressed cortical network activity followed by normal maturation. No post-injury seizures were seen. The participation in network activity of individual neurons destined to die was indistinguishable from those that survived for 4 days post-injury. In conclusion, our results showed that mild perinatal brain injury resulted in a prolonged increase of neuronal death. Neurons that died late were functioning normally for days after injury, suggesting a new pathophysiology of neuronal death. Critically, the neurons destined to die late demonstrated multiple biomarkers of viability long after mild injury, suggesting their later death may be modified with neuroprotective interventions.
Neonatal encephalopathy due to peripartum hypoxia-ischemia (HI) is a major cause of neonatal mortality and morbidity worldwide. Of these infants, most are categorized as having mild HI. Infants with mild HI have significant long-term disabilities. There are currently no evidence-based therapies, largely because the progression and pathophysiology of mild injury is poorly understood. We have identified, for the first time, that mild perinatal HI results in a delayed and prolonged increase in neuronal death. The cortical and hippocampal neurons that die over a week after injury participate normally in neural network activity and exhibit robust viability for many days after injury, indicating a novel pathophysiology of neuronal death. Clinically, these data suggest an extended therapeutic window for mild perinatal HI.
轻度缺氧缺血性脑病在新生儿中很常见,且尚无循证疗法,30%-40%的患者会出现不良后果。人们对轻度损伤的性质和进展了解甚少。因此,我们使用转基因荧光蛋白的纵向双光子成像技术,以细胞分辨率对神经元活力和活性进行全新测定,研究了轻度围产期脑损伤的演变过程。在体外,对围产期小鼠海马器官型培养物进行15-20分钟的氧糖剥夺处理。在体内,对出生后第10天的雌雄小鼠幼崽进行颈动脉结扎和15分钟的缺氧处理,造成轻度缺氧缺血。与轻度损伤一致,损伤后即刻可见极少的神经元死亡,且在损伤后2.5周通过离体磁共振成像未发现损伤的体积证据。在海马体和新皮质中,这些轻度损伤导致损伤后第二周神经元显著延迟性且进行性丧失,通过荧光团淬灭进行测定。轻度缺氧缺血短暂抑制皮质网络活动,随后正常成熟。未观察到损伤后癫痫发作。注定死亡的单个神经元在损伤后4天内参与网络活动的情况与存活神经元并无差异。总之,我们的结果表明,轻度围产期脑损伤导致神经元死亡持续时间延长。晚期死亡的神经元在损伤后数天内功能正常,提示神经元死亡存在新的病理生理学机制。关键的是,注定晚期死亡的神经元在轻度损伤后很长时间内表现出多种活力生物标志物,表明其晚期死亡可能通过神经保护干预措施得到改善。
围产期缺氧缺血(HI)所致的新生儿脑病是全球新生儿死亡和发病的主要原因。在这些婴儿中,大多数被归类为轻度HI。轻度HI的婴儿有显著的长期残疾。目前尚无循证疗法,主要是因为对轻度损伤的进展和病理生理学了解甚少。我们首次发现,轻度围产期HI导致神经元死亡延迟且持续时间延长。损伤一周后死亡的皮质和海马神经元正常参与神经网络活动,且在损伤后数天内表现出强大的活力,表明存在神经元死亡的新病理生理学机制。临床上,这些数据提示轻度围产期HI存在延长的治疗窗口期。
