尿CXCL10水平对PICU重症患儿死亡风险的预测价值
Predictive value of urinary CXCL10 for mortality risk of critically ill children in PICU
Received date: 2023-08-30
Online published: 2024-07-08
目的 探讨尿C-X-C基序趋化因子10(CXCL10)水平对重症患儿住儿科重症监护病房(PICU)期间死亡风险的预测价值。方法 选择2016年9月至12月以及2017年12月至2018年1月PICU收治的323例重症患儿作为研究对象。根据入住PICU期间转归情况分为生存组(295例)和死亡组(28例),比较组间患儿临床特征。采用酶联免疫吸附法检测患儿入住PICU第1周尿CXCL10水平的动态变化。运用多因素逐步线性回归分析明确尿CXCL10水平与临床变量的相关性。多因素logistic回归分析评估在校正混杂因素后尿CXCL10与病死率的关系,采用受试者工作特征曲线下面积(AUC)评估尿CXCL10对重症患儿病死率的预测价值。结果 死亡组尿CXCL10初始值和最大值均明显高于生存组(P<0.05)。多因素线性和logistic回归分析均显示尿CXCL10的初始值及最大值与死亡显著相关(P<0.05)。尿CXCL10初始和最大值预测重症患儿死亡的AUC值分别为0.780(95%CI:0.689~0.872,P<0.001)、0.846(95%CI:0.769~0.923,P<0.001)。结论 尿CXCL10是重症患儿死亡的独立预测指标。
冯恋 , 胡俊龙 , 黄慧 , 李晓忠 , 李艳红 . 尿CXCL10水平对PICU重症患儿死亡风险的预测价值[J]. 临床儿科杂志, 2024 , 42(7) : 631 -636 . DOI: 10.12372/jcp.2024.23e0856
Objective To investigate the predictive value of urinary CXC motif chemokine ligand 10 (uCXCL10) in the risk of death in critically ill children during their stay in the pediatric intensive care unit (PICU). Methods A total of 323 critically ill children admitted to PICU from September to December 2016 and from December 2017 to January 2018 were selected as the research objects. The patients were divided into survival group (295 cases) and death group (28 cases) according to the outcome during hospitalization in PICU, and the clinical characteristics of the children were compared between the groups. The uCXCL10 levels were serially measured during the first week after PICU admission using an enzyme-linked immunosorbent assay. Stepwise multivariate linear regression analysis were used to determine the correlation between uCXCL10 levels and clinical variables. Multivariate logistic regression analysis were performed to investigate the association of uCXCL10 with mortality after adjusting for confounders. The area under the ROC curve (AUC) was calculated to assess the predictive value of uCXCL10 in mortality of critically ill children. Results The initial and maximum values of uCXCL10 in the death group were significantly higher than those in the survival group (P<0.05). Both stepwise multivariate linear regression and multivariate logistic regression analysis showed that the initial and maximum values of uCXCL10 were significantly associated with mortality (P<0.05). The AUC values of initial and maximum uCXCL10 for predicting death in critically ill children were 0.780 (95%CI: 0.689-0.872, P<0.001) and 0.846 (95%CI: 0.769-0.923, P<0.001), respectively. Conclusion The uCXCL10 is an independent predictor of death in critically ill children.
| [1] | Gemke RJ, van Vught J. Scoring systems in pediatric intensive care: PRISM III versus PIM[J]. Intensive Care Med, 2002, 28(2): 204-207. |
| [2] | Joyce EL, Crana CM, Yabes J, et al. Validation of an electronic pediatric index of mortality 2 score in a mixed quaternary PICU[J]. Pediatr Crit Care Med, 2020, 21(8): e572-e575. |
| [3] | Matics TJ, Sanchez-Pinto LN. Adaptation and validation of a pediatric sequential organ failure assessment score and evaluation of the sepsis-3 definitions in critically ill children[J]. JAMA Pediatr, 2017, 171(10): e172352. |
| [4] | Tonial CT, Costa C, Andrades G, et al. Performance of prognostic markers in pediatric sepsis[J]. J Pediatr (Rio J), 2021, 97(3): 287-294. |
| [5] | Rey C, Fortenberry JD. Prognostic markers for pediatric septic shock: which ones, when, and how?[J]. Intensive Care Med, 2013, 39(10): 1851-1853. |
| [6] | Anil AB, Anil M, Yildiz M, et al. The importance of microalbuminuria in predicting patient outcome in a PICU[J]. Pediatr Crit Care Med, 2014, 15(5): e220-e225. |
| [7] | Nismath S, Rao SS, Baliga BS, et al. Comparative validity of microalbuminuria versus clinical mortality scores to predict pediatric intensive care unit outcomes[J]. Clin Exp Pediatr, 2020, 63(1): 20-24. |
| [8] | Antonelli A, Ferrari SM, Giuggioli D, et al. Chemokine (C-X-C motif) ligand (CXCL)10 in autoimmune diseases[J]. Autoimmun Rev, 2014, 13(3): 272-280. |
| [9] | Elemam NM, Talaat IM, Maghazachi AA. CXCL10 chemokine: a critical player in RNA and DNA viral infections[J]. Viruses, 2022, 14(11): 2445. |
| [10] | Gao J, Wu L, Wang S, et al. Role of chemokine (C-X-C Motif) ligand 10 (CXCL10) in renal diseases[J]. Mediators Inflamm, 2020: 6194864. |
| [11] | Liu M, Guo S, Hibbert JM, et al. CXCL10/IP-10 in infectious diseases pathogenesis and potential therapeutic implications[J]. Cytokine Growth Factor Rev, 2011, 22(3): 121-130. |
| [12] | Jekarl DW, Kim JY, Ha JH, et al. Diagnosis and prognosis of sepsis based on use of cytokines, chemokines, and growth factors[J]. Dis Markers, 2019: 1089107. |
| [13] | Erez DL, Denburg MR, Afolayan S, et al. Acute kidney injury in children after hematopoietic cell transplantation is associated with elevated urine CXCL10 and CXCL9[J]. Biol Blood Marrow Transplant, 2020, 26(7): 1266-1272. |
| [14] | Huang H, Zhou H, Wang W, et al. Prediction of acute kidney injury, sepsis and mortality in children with urinary CXCL10[J]. Pediatr Res, 2022, 92(2): 541-548. |
| [15] | Hoste E, Kellum JA, Selby NM, et al. Global epidemiology and outcomes of acute kidney injury[J]. Nat Rev Nephrol, 2018, 14(10): 607-625. |
| [16] | Rudd KE, Johnson SC, Agesa KM, et al. Global, regional, and national sepsis incidence and mortality, 1990-2017: analysis for the Global Burden of Disease Study[J]. Lancet, 2020, 395(10219): 200-211. |
| [17] | Amecican Academy of Pediatrics, Commitee on Hospitial Care and Society of Critial Care, Society of Critial Care Medicine, et al. Guidelines for developing admission and discharge policies for the pediatric[J]. Pediatrics, 1999(103): 840-842. |
| [18] | Weiss SL, Peters MJ, Alhazzani W, et al. Executive summary: surviving sepsis campaign international guidelines for the management of septic shock and sepsis-associated organ dysfunction in children[J]. Pediatr Crit Care Med, 2020, 21(2): 186-195. |
| [19] | Khwaja A. KDIGO clinical practice guidelines for acute kidney injury[J]. Nephron Clin Pract, 2012, 120(4): c179-c184. |
| [20] | Fang F, Hu X, Dai X, et al. Subclinical acute kidney injury is associated with adverse outcomes in critically ill neonates and children[J]. Crit Care, 2018, 22(1): 256. |
| [21] | Herzig DS, Luan L, Bohannon JK, et al. The role of CXCL10 in the pathogenesis of experimental septic shock[J]. Crit Care, 2014, 18(3): R113. |
| [22] | Lee EY, Lee ZH, Song YW. CXCL10 and autoimmune diseases[J]. Autoimmun Rev, 2009, 8(5): 379-383. |
| [23] | Chan T, Gu F. Early diagnosis of sepsis using serum biomarkers[J]. Expert Rev Mol Diagn, 2011, 11(5):487-496. |
| [24] | Vaidya VS, Waikar SS, Ferguson MA, et al. Urinary biomarkers for sensitive and specific detection of acute kidney injury in humans[J]. Clin Transl Sci, 2008, 1(3): 200-208. |
| [25] | 程创, 石中全. miR-16-5p靶向抑制CXCL10表达减轻脂多糖诱导的HK-2人肾小管上皮细胞损伤[J]. 细胞与分子免疫学杂志, 2022, 38(3): 218-223. |
| [26] | Kirita Y, Wu H, Uchimura K, et al. Cell profiling of mouse acute kidney injury reveals conserved cellular responses to injury[J]. Proc Natl Acad Sci U S A, 2020, 117(27): 15874-15883. |
| [27] | Lehmann JM, Claus K, Jansen C, et al. Circulating CXCL10 in cirrhotic portal hypertension might reflect systemic inflammation and predict ACLF and mortality[J]. Liver Int, 2018, 38(5): 875-884. |
| [28] | Landreneau MJ, Mullen MT, Messe SR, et al. CCL2 and CXCL10 are associated with poor outcome after intracerebral hemorrhage[J]. Ann Clin Transl Neurol, 2018, 5(8): 962-970. |
| [29] | Tinel C, Vermorel A, Picciotto D, et al. Deciphering the prognostic and predictive value of urinary CXCL10 in kidney recipients with BK virus reactivation[J]. Front Immunol, 2020, 11: 604353. |
| [30] | Tinel C, Devresse A, Vermorel A, et al. Development and validation of an optimized integrative model using urinary chemokines for noninvasive diagnosis of acute allograft rejection[J]. Am J Transplant, 2020, 20(12): 3462-3476. |
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