Sellers-Porter Camryn, Lueschow-Guijosa Shiloh R, Santana Jessica M, Cera Anjali J, Bautista Geoanna M, Persiani Michele, Good Misty, McElroy Steven J
Department of Pediatrics, University of California, Davis, Davis, CA, United States.
Department of Pediatrics, University of Iowa Health Care, Iowa City, IA, United States.
Front Cell Infect Microbiol. 2025 Jun 10;15:1589712. doi: 10.3389/fcimb.2025.1589712. eCollection 2025.
Neonatal sepsis is a major cause of neonatal morbidity and mortality. Reliable animal models are essential to our understanding of late-onset sepsis, but notable limitations exist in the current standard murine cecal slurry model. We sought to refine the existing model by using an injection of known stock slurry ("NEC'teria") cultured from an infant who died of necrotizing enterocolitis to better mimic sepsis following the translocation of neonatal specific bacterial pathogens from the intestine into the peritoneum.
To induce sepsis, neonatal mice (P7 and P14 - P16) were given an intraperitoneal injection of varying concentrations of NEC'teria, while sham controls received an injection of PBS. Mice were monitored for survival and tissue samples, serum, and peritoneal washes were collected for further assessment of inflammation, immune response, and intestinal injury. Ceca were collected for microbiome analysis.
While the polymicrobial cecal slurry from adult mice contained common healthy gut microbes, NEC'teria is composed of bacteria, primarily from the Enterobacteriaceae and Enterococcaceae families, that are common causes of late-onset sepsis. NEC'teria exposure significantly increased serum inflammatory cytokines, resulted in intestinal injury, altered the microbiome composition, and induced significant changes in local and systemic immune cell expression. Sepsis-induced mortality, inflammation, and intestinal injury were live-bacteria dependent and could be attenuated by administration of an antibiotic one hour after bacterial injection.
Our modification to the cecal slurry neonatal sepsis model resulted in a consistent sepsis-related mortality and phenotypic changes in neonatal mouse pups that resembled the changes that occur in human preterm infants who develop late-onset sepsis. Our pathogenic slurry is highly relevant to neonatal sepsis, as it is comprised of bacterial families found commonly in septic neonates. We expect our model to be highly reproducible between institutions, due to the standardized bacterial dose and characterized stock solution.
新生儿败血症是新生儿发病和死亡的主要原因。可靠的动物模型对于我们理解迟发性败血症至关重要,但当前标准的小鼠盲肠灌洗液模型存在显著局限性。我们试图通过注射从一名死于坏死性小肠结肠炎的婴儿身上培养的已知储备灌洗液(“NEC'teria”)来改进现有模型,以更好地模拟新生儿特定细菌病原体从肠道转移至腹膜后引发的败血症。
为诱导败血症,给新生小鼠(出生后第7天以及出生后第14 - 16天)腹腔注射不同浓度的NEC'teria,而假手术对照组注射磷酸盐缓冲液(PBS)。监测小鼠的存活情况,并收集组织样本、血清和腹腔灌洗液,以进一步评估炎症、免疫反应和肠道损伤。收集盲肠用于微生物组分析。
成年小鼠的多微生物盲肠灌洗液含有常见的健康肠道微生物,而NEC'teria由主要来自肠杆菌科和肠球菌科的细菌组成,这些细菌是迟发性败血症的常见病因。接触NEC'teria显著增加了血清炎症细胞因子水平,导致肠道损伤,改变了微生物组组成,并诱导局部和全身免疫细胞表达发生显著变化。败血症诱导的死亡率、炎症和肠道损伤依赖于活菌,并且在细菌注射后一小时给予抗生素可使其减轻。
我们对盲肠灌洗液新生儿败血症模型的改进导致新生小鼠出现了与败血症相关的一致死亡率和表型变化,这些变化类似于发生在发生迟发性败血症的人类早产儿身上的变化。我们的致病性灌洗液与新生儿败血症高度相关,因为它由败血症新生儿中常见的细菌家族组成。由于细菌剂量标准化且储备溶液特性明确,我们预计我们的模型在不同机构之间具有高度可重复性。
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