The risk prediction models for pneumonia in patients with intracerebral hemorrhage: A systematic review

doi:10.3969/j.issn.1004-583X.2025.01.001

Abstract

Abstract:

Objective To systematically analyze and evaluate the risk prediction model for pneumonia in patients with intracerebral hemorrhage (ICH). Methods Articles reporting risk prediction model for pneumonia in ICH patients published prior to February 2023 were searched in the online databases of Pubmed, Web of Science, Embase, The Cochrane Library, Scopus, Ovid Medline, CNKI (China National Knowledge Infrastructure), WanFang Data, VIP and CBM (Chinese Biomedical Literature Database). Two researchers were independently responsible for screening literature and extracting data. The quality of the literature included in this study was rigorously evaluated, and both the risk of bias and adaptability were assessed in accordance with the Transparent Reporting of a Multivariable Prediction Model for Individal Prognosis or Diagnosis(TRIPOD), and the Prediction Model Risk of Bias Assessment Tool(PROBAST). Results A total of 12 relevant studies were included, involving 7 registered studies, 1 ovarian case-control study, 3 single-center case-control studies, and 1 retrospective cohort study. Logistic regression and machine learning were used for modeling. Eight studies were validated internally, 2 studies were only validated externally, and 2 studies were validated both. The area under the receiver operating characteristic curve of the model was 0.740-0.920. The range of predictors in the 12 studies ranged from 4 to 11, and the common predictors were the age, the National Institutes of Health Stroke Scale score, the Glasgow Coma Scale score, dysphagia, smoking, chronic obstructive pulmonary disease, and nasogastric tube feeding. Model calibration was performed in 9 studies and not in 3 studies. The model was mainly presented in the form of risk score, risk calculation formula and nomogram. The included studies exhibited moderate quality and a high risk of bias. Conclusion The current model for predicting the risk of pneumonia in ICH patients demonstrates good predictive ability, and the predictive factors are relatively easy to obtain. However, there are also significant defects and high bias. In future research, it is recommended that researchers adhere to the TRIPOD guideline and PROBAST statement when conducting prediction model studies. It is important to summarize the advantages and disadvantages of existing models and to conduct external verification, thus developing a risk prediction model for pneumonia in ICH patients with excellent predictive performance and ease of use.

Key words: intracerebral hemorrhage, pneumonia, prediction model, systematic review

CLC Number:

Liu Jinteng, Liu Xingyu, Huang Lumei, Pan Hailong. The risk prediction models for pneumonia in patients with intracerebral hemorrhage: A systematic review[J]. Clinical Focus, 2025, 40(1): 5-13.

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URL: https://huicui.hebmu.edu.cn/EN/10.3969/j.issn.1004-583X.2025.01.001

https://huicui.hebmu.edu.cn/EN/Y2025/V40/I1/5

Figures/Tables 4

Fig.1 A flow chart of included literatures

Tab.1 Basic characteristics of included literatures

第一作者	发表年份	国家/ 地区	模型类型	研究类型	研究对象来源	样本量	建模方法	验模方法	结局指标	肺炎发生率
Zheng等^[14]	2022	中国	开发及验证	注册登记研究	2015年1月- 2020年7月急性ICH患者风险分层和微创手术(Risa-MIS-ICH)数据库( $n$ =468)	A:324; C:144	逻辑回归(LR),高斯朴素贝叶斯(GNB),集成软投票模型(ESVM)	内部验证+外部验证	SAP发生	-
Ji等^[15]	2014	中国	开发及验证	注册登记研究	2007年9月- 2008年8月中国国家卒中登记处(CNSR)( $n$ =4 998)	A:2 998; B:2 000	多因素logistic回归	内部验证	肺炎发生	A:16.40%; B:17.70%
Yan等^[16]	2022	中国	开发及验证	注册登记研究	2015-2018年中国卒中中心联盟(CSCA)( $n$ =70 542) 2019年中国国家卒中注册管理系统II (CNSR II)( $n$ =12 523)	A:56 432; B:14 108; C:12 523	XGboost树模型和logistic回归	内部验证+外部验证	肺炎发生	-
Smith等^[17]	2015	英国	开发及验证	注册登记研究	2013年1-9月中风国家审计计划多中心英国登记处(SSNAP)( $n$ =1 865)	A:916; B:949	多因素logistic回归	内部验证	SAP发生	A:- B:风险组Ⅰ:2.80%; 风险组Ⅱ:7.40%; 风险组Ⅲ:15.70%; 风险组Ⅳ:21.90%
宋甜田等^[18]	2021	中国	开发及验证	巢式病例对照研究	2016-2018年山东省某医院ICH手术患者( $n$ =603)	A:422; B:181	多因素logistic回归	内部验证	肺部感染发生	A:风险组Ⅰ:4.47%; 风险组Ⅱ:21.28%; 风险组Ⅲ:58.65%; B:风险组Ⅰ:4.55%; 风险组Ⅱ:21.28%; 风险组Ⅲ:65.22%
李景余等^[19]	2022	中国	开发及验证	回顾性队列研究	2019年1月-2020年12月潍坊市某三级甲等医院的ICH术后病人( $n$ =298)	A:209; B:89	多因素logistic回归	内部验证	肺部感染发生	A:17.22%; B:20.22%
吴珂等^[20]	2022	中国	开发及验证	病例对照研究	2014年6月-2019年6月于宜宾市第一人民医院行手术治疗的自发性ICH患者( $n$ =768)	A:768	多因素logistic回归	内部验证 (Bootstrap法)	肺部感染发生	A:25.78% ; B:-
廖峻等^[21]	2022	中国	开发及验证	病例对照研究	2019年11月-2021年11月成都大学附属医院因高血压ICH住院治疗的患者( $n$ =160)	A:160	多因素logistic回归	内部验证 (Bootstrap法 1 000次抽样)	呼吸机相关肺炎发生	A:26.86%; B:-
Papavasileiou等^[22]	2015	希腊	验证	注册登记研究	1992年6月-2011年12月雅典卒中登记处(ASR)( $n$ =472)	C:472	-	外部验证	SAP发生	C:风险组Ⅰ:-; 风险组Ⅱ:4.80%; 风险组Ⅲ:7.40%; 风险组Ⅳ:11.10%
吴倩等^[23]	2020	中国	开发及验证	病例对照研究	2017年12月-2019年12月因急性ICH入院的老年患者( $n$ =173)	A:173	多因素logistic回归	内部验证 (Bootstrap法)	SAP发生	A:25.43%; B:-
Zhang等^[24]	2017	中国	验证	注册登记研究	2012年5月-2013年1月中国国家卒中登记处(CNSR)( $n$ =4 933)	C:4 933	-	外部验证	SAP发生	C:风险组Ⅰ:8.40%; 风险组Ⅱ:19.60%; 风险组Ⅲ:30.10%; 风险组Ⅳ:42.50%
王孟等^[25]	2020	中国	开发及验证	注册登记研究	2012年5月-2013年1月中国国家卒中登记Ⅱ数据库(CNSRⅡ)( $n$ =2 303)	A:1 841; B:462	logistic回归、CatBoost、XGBoost和LightGBM算法	内部验证	肺炎发生	A:15.60%; B:15.80%

Tab.1 Basic characteristics of included literatures

第一作者	发表年份	国家/ 地区	模型类型	研究类型	研究对象来源	样本量	建模方法	验模方法	结局指标	肺炎发生率
Zheng等^[14]	2022	中国	开发及验证	注册登记研究	2015年1月- 2020年7月急性ICH患者风险分层和微创手术(Risa-MIS-ICH)数据库( $n$ =468)	A:324; C:144	逻辑回归(LR),高斯朴素贝叶斯(GNB),集成软投票模型(ESVM)	内部验证+外部验证	SAP发生	-
Ji等^[15]	2014	中国	开发及验证	注册登记研究	2007年9月- 2008年8月中国国家卒中登记处(CNSR)( $n$ =4 998)	A:2 998; B:2 000	多因素logistic回归	内部验证	肺炎发生	A:16.40%; B:17.70%
Yan等^[16]	2022	中国	开发及验证	注册登记研究	2015-2018年中国卒中中心联盟(CSCA)( $n$ =70 542) 2019年中国国家卒中注册管理系统II (CNSR II)( $n$ =12 523)	A:56 432; B:14 108; C:12 523	XGboost树模型和logistic回归	内部验证+外部验证	肺炎发生	-
Smith等^[17]	2015	英国	开发及验证	注册登记研究	2013年1-9月中风国家审计计划多中心英国登记处(SSNAP)( $n$ =1 865)	A:916; B:949	多因素logistic回归	内部验证	SAP发生	A:- B:风险组Ⅰ:2.80%; 风险组Ⅱ:7.40%; 风险组Ⅲ:15.70%; 风险组Ⅳ:21.90%
宋甜田等^[18]	2021	中国	开发及验证	巢式病例对照研究	2016-2018年山东省某医院ICH手术患者( $n$ =603)	A:422; B:181	多因素logistic回归	内部验证	肺部感染发生	A:风险组Ⅰ:4.47%; 风险组Ⅱ:21.28%; 风险组Ⅲ:58.65%; B:风险组Ⅰ:4.55%; 风险组Ⅱ:21.28%; 风险组Ⅲ:65.22%
李景余等^[19]	2022	中国	开发及验证	回顾性队列研究	2019年1月-2020年12月潍坊市某三级甲等医院的ICH术后病人( $n$ =298)	A:209; B:89	多因素logistic回归	内部验证	肺部感染发生	A:17.22%; B:20.22%
吴珂等^[20]	2022	中国	开发及验证	病例对照研究	2014年6月-2019年6月于宜宾市第一人民医院行手术治疗的自发性ICH患者( $n$ =768)	A:768	多因素logistic回归	内部验证 (Bootstrap法)	肺部感染发生	A:25.78% ; B:-
廖峻等^[21]	2022	中国	开发及验证	病例对照研究	2019年11月-2021年11月成都大学附属医院因高血压ICH住院治疗的患者( $n$ =160)	A:160	多因素logistic回归	内部验证 (Bootstrap法 1 000次抽样)	呼吸机相关肺炎发生	A:26.86%; B:-
Papavasileiou等^[22]	2015	希腊	验证	注册登记研究	1992年6月-2011年12月雅典卒中登记处(ASR)( $n$ =472)	C:472	-	外部验证	SAP发生	C:风险组Ⅰ:-; 风险组Ⅱ:4.80%; 风险组Ⅲ:7.40%; 风险组Ⅳ:11.10%
吴倩等^[23]	2020	中国	开发及验证	病例对照研究	2017年12月-2019年12月因急性ICH入院的老年患者( $n$ =173)	A:173	多因素logistic回归	内部验证 (Bootstrap法)	SAP发生	A:25.43%; B:-
Zhang等^[24]	2017	中国	验证	注册登记研究	2012年5月-2013年1月中国国家卒中登记处(CNSR)( $n$ =4 933)	C:4 933	-	外部验证	SAP发生	C:风险组Ⅰ:8.40%; 风险组Ⅱ:19.60%; 风险组Ⅲ:30.10%; 风险组Ⅳ:42.50%
王孟等^[25]	2020	中国	开发及验证	注册登记研究	2012年5月-2013年1月中国国家卒中登记Ⅱ数据库(CNSRⅡ)( $n$ =2 303)	A:1 841; B:462	logistic回归、CatBoost、XGBoost和LightGBM算法	内部验证	肺炎发生	A:15.60%; B:15.80%

Tab.2 Basic characteristics of prediction models of included literatures

第一作者	预测因子	变量选择方法	模型呈现形式	AUC(95% $C I$ )/灵敏度/特异度	校准方法
Zheng等^[14]	鼻胃管喂养、气道支持、起病无意识、心室外引流手术、更大的自发性ICH体积、ICU住院时间	单因素分析,LASSO回归	-	LR:A- B:AUC值0.838(0.765~0.911),Sc:0.615,Sp:0.903; C:AUC值0.867(0.812~0.923),Sc:0.447,Sp:0.943; GNB:A- B:AUC值0.861(0.793~0.930),Sc:0.615,Sp:0.889; C:AUC值0.856(0.798~0.913),Sc:0.553,Sp:0.934; ESVM:A- B:AUC值0.830(0.756~0.904),Sc:0.615,Sp:0.917; C:AUC值0.843(0.658~0.803),Sc:0.447,Sp:0.943;	-
Ji等^[15]	模型1:年龄、当前吸烟、饮酒COPD、mRS≥3、GCS评分、NIHSS评分、吞咽困难、ICH部位、脑室扩大模型2:年龄、当前吸烟、饮酒COPD、mRS≥3、GCS评分、NIHSS评分、吞咽困难、幕下占位、脑室扩大、血肿体积	单因素和多因logistic回归,逐步向后法	根据标准化β值对每个风险因素进行评分,计算个体发病总分	模型1:A:AUC值0.750(0.720~0.770),Sc:-,Sp:-; B:AUC值0.760(0.710~0.790),Sc:-,Sp:-; 模型2:A:AUC值0.740(0.710~0.760),Sc:-,Sp:-; B:AUC值0.730(0.700~0.760),Sc:-,Sp:-;	H-L拟合优度检验
Yan等^[16]	吞咽困难、GCS评分、年龄、空腹血糖值、COPD、NIHSS评分、mRS、当前吸烟和C反应蛋白	-	基于逻辑回归,风险评分使用权重系数,得到对应的特征得分和数值区间	A:AUC值0.749(0.739~0.759),Sc:-,Sp:-; B:- C:AUC值0.784(0.774~0.794),Sc:-,Sp:-;	-
Smith等^[17]	性别、年龄、中风前独立性、NIHSS评分	多因素logistic回归	根据各因子的回归系数对其进行赋分,计算个体的发病风险总分,低风险(0~5分)、中等风险(6~10分)、高风险(11~14分)和最高风险(15≥分)	B:AUC值0.710(0.660~0.770),Sc:-,Sp:-	校准曲线
宋甜田等^[18]	气管插管,留置胃管,静脉血栓,ASA分级	单因素和多因素logistic回归,用Back-Wald法筛选变量	依据β×4构建风险预测评分模型;0~ 6分为低风险组,7~12分为中风险组,13~21分为高风险组	A:AUC值0.864(0.825~0.904),Sc:-,Sp:- B:AUC值0.861(0.800~0.921),Sc:-,Sp:-	H-L拟合优度检验
李景余等^[19]	术前GCS评分,ASA分级,留置胃管,白细胞计数,机械通气时间	单因素和多因logistic回归	Logit(P)=-3.591+0.873×术前GCS评分+0.674×ASA分级+0.842×留置胃管+0.536×白细胞计数+1.469×机械通气时间	A:AUC值0.748(0.664~0.833),Sc:0.861,Sp:0.601 B:AUC值0.718(0.626~0.810),Sc:0.852,Sp:0.690	H-L拟合优度检验
吴柯等^[20]	年龄≥60岁、吸烟、糖尿病、呼吸机使用时间≥3 d、GCS评分≤8分、低蛋白血症	向前法进行多因素logistic回归	列线图预测模型,读取各因子的值对应的得分,将所有因子的得分相加	A:AUC值0.920(0.900~0.941),Sc:-,Sp:-	H-L拟合优度检验
廖峻等^[21]	COPD、低蛋白血症、ICU住院时间、机械通气时间	单因素和多因素logistic回归	基于最小二乘法Logit(P)=-5.298+1.070×合并慢性阻塞性肺疾病+0.925×低蛋白血症+1.141×ICU住院时间+1.355×机械通气时间	A:AUC值0.888(0.829~0.933),Sc:74.42%,Sp:88.89%	H-L拟合优度检验
Papavasileiou等^[22]	性别、年龄、中风前独立性、NIHSS评分	-	低风险(0~5分)、中等风险(6~10分)、高风险(11~14分)和最高风险(15≥分)	C:AUC值0.690(0.630~0.740),Sc:-,Sp:-	H-L拟合优度检验,皮尔逊相关系数
吴倩等^[23]	年龄、肺部基础疾病、吞咽困难、NIHSS评分、侵入性气道操作、鼻饲治疗、预防性使用抑酸剂	单因素和多因logistic回归	列线图预测模型,读取各因子的值对应的得分,将所有因子的得分相加	A:AUC值0.843(0.811~0.875),Sc:-,Sp:-	校准曲线
Zhang等^[24]	性别、年龄、中风前独立性、NIHSS评分	-	低风险(0~5分)、中等风险(6~10分)、高风险(11~14分)和最高风险(15≥分)	C:AUC值0.700(0.680~0.720),Sc:-,Sp:-	H-L拟合优度检验,皮尔逊相关系数
王孟等^[25]	年龄、吞咽困难、NIHSS评分、白细胞计数	单因素和多因logistic回归,逐步向后法筛选变量	-	logistic回归:A:AUC值0.778(-),Sc:64.58%,Sp:79.14%; B:AUC值0.776(-),Sc:75.34%,Sp:69.15%; CaBoost:A:AUC值0.758(-),Sc:57.29%,Sp:85.06%; B:AUC值0.692(-),Sc:50.68%,Sp:86.12%; XGBoost:A:AUC值0.844(-),Sc:73.61%,Sp:80.81%; B:AUC值0.736(-),Sc:80.82%,Sp:52.96%; LightGBM:A:AUC值0.822(-),Sc:70.14%,Sp:80.68%; B:AUC值0.767(-),Sc:80.82%,Sp:57.33%	-

Tab.2 Basic characteristics of prediction models of included literatures

第一作者	预测因子	变量选择方法	模型呈现形式	AUC(95% $C I$ )/灵敏度/特异度	校准方法
Zheng等^[14]	鼻胃管喂养、气道支持、起病无意识、心室外引流手术、更大的自发性ICH体积、ICU住院时间	单因素分析,LASSO回归	-	LR:A- B:AUC值0.838(0.765~0.911),Sc:0.615,Sp:0.903; C:AUC值0.867(0.812~0.923),Sc:0.447,Sp:0.943; GNB:A- B:AUC值0.861(0.793~0.930),Sc:0.615,Sp:0.889; C:AUC值0.856(0.798~0.913),Sc:0.553,Sp:0.934; ESVM:A- B:AUC值0.830(0.756~0.904),Sc:0.615,Sp:0.917; C:AUC值0.843(0.658~0.803),Sc:0.447,Sp:0.943;	-
Ji等^[15]	模型1:年龄、当前吸烟、饮酒COPD、mRS≥3、GCS评分、NIHSS评分、吞咽困难、ICH部位、脑室扩大模型2:年龄、当前吸烟、饮酒COPD、mRS≥3、GCS评分、NIHSS评分、吞咽困难、幕下占位、脑室扩大、血肿体积	单因素和多因logistic回归,逐步向后法	根据标准化β值对每个风险因素进行评分,计算个体发病总分	模型1:A:AUC值0.750(0.720~0.770),Sc:-,Sp:-; B:AUC值0.760(0.710~0.790),Sc:-,Sp:-; 模型2:A:AUC值0.740(0.710~0.760),Sc:-,Sp:-; B:AUC值0.730(0.700~0.760),Sc:-,Sp:-;	H-L拟合优度检验
Yan等^[16]	吞咽困难、GCS评分、年龄、空腹血糖值、COPD、NIHSS评分、mRS、当前吸烟和C反应蛋白	-	基于逻辑回归,风险评分使用权重系数,得到对应的特征得分和数值区间	A:AUC值0.749(0.739~0.759),Sc:-,Sp:-; B:- C:AUC值0.784(0.774~0.794),Sc:-,Sp:-;	-
Smith等^[17]	性别、年龄、中风前独立性、NIHSS评分	多因素logistic回归	根据各因子的回归系数对其进行赋分,计算个体的发病风险总分,低风险(0~5分)、中等风险(6~10分)、高风险(11~14分)和最高风险(15≥分)	B:AUC值0.710(0.660~0.770),Sc:-,Sp:-	校准曲线
宋甜田等^[18]	气管插管,留置胃管,静脉血栓,ASA分级	单因素和多因素logistic回归,用Back-Wald法筛选变量	依据β×4构建风险预测评分模型;0~ 6分为低风险组,7~12分为中风险组,13~21分为高风险组	A:AUC值0.864(0.825~0.904),Sc:-,Sp:- B:AUC值0.861(0.800~0.921),Sc:-,Sp:-	H-L拟合优度检验
李景余等^[19]	术前GCS评分,ASA分级,留置胃管,白细胞计数,机械通气时间	单因素和多因logistic回归	Logit(P)=-3.591+0.873×术前GCS评分+0.674×ASA分级+0.842×留置胃管+0.536×白细胞计数+1.469×机械通气时间	A:AUC值0.748(0.664~0.833),Sc:0.861,Sp:0.601 B:AUC值0.718(0.626~0.810),Sc:0.852,Sp:0.690	H-L拟合优度检验
吴柯等^[20]	年龄≥60岁、吸烟、糖尿病、呼吸机使用时间≥3 d、GCS评分≤8分、低蛋白血症	向前法进行多因素logistic回归	列线图预测模型,读取各因子的值对应的得分,将所有因子的得分相加	A:AUC值0.920(0.900~0.941),Sc:-,Sp:-	H-L拟合优度检验
廖峻等^[21]	COPD、低蛋白血症、ICU住院时间、机械通气时间	单因素和多因素logistic回归	基于最小二乘法Logit(P)=-5.298+1.070×合并慢性阻塞性肺疾病+0.925×低蛋白血症+1.141×ICU住院时间+1.355×机械通气时间	A:AUC值0.888(0.829~0.933),Sc:74.42%,Sp:88.89%	H-L拟合优度检验
Papavasileiou等^[22]	性别、年龄、中风前独立性、NIHSS评分	-	低风险(0~5分)、中等风险(6~10分)、高风险(11~14分)和最高风险(15≥分)	C:AUC值0.690(0.630~0.740),Sc:-,Sp:-	H-L拟合优度检验,皮尔逊相关系数
吴倩等^[23]	年龄、肺部基础疾病、吞咽困难、NIHSS评分、侵入性气道操作、鼻饲治疗、预防性使用抑酸剂	单因素和多因logistic回归	列线图预测模型,读取各因子的值对应的得分,将所有因子的得分相加	A:AUC值0.843(0.811~0.875),Sc:-,Sp:-	校准曲线
Zhang等^[24]	性别、年龄、中风前独立性、NIHSS评分	-	低风险(0~5分)、中等风险(6~10分)、高风险(11~14分)和最高风险(15≥分)	C:AUC值0.700(0.680~0.720),Sc:-,Sp:-	H-L拟合优度检验,皮尔逊相关系数
王孟等^[25]	年龄、吞咽困难、NIHSS评分、白细胞计数	单因素和多因logistic回归,逐步向后法筛选变量	-	logistic回归:A:AUC值0.778(-),Sc:64.58%,Sp:79.14%; B:AUC值0.776(-),Sc:75.34%,Sp:69.15%; CaBoost:A:AUC值0.758(-),Sc:57.29%,Sp:85.06%; B:AUC值0.692(-),Sc:50.68%,Sp:86.12%; XGBoost:A:AUC值0.844(-),Sc:73.61%,Sp:80.81%; B:AUC值0.736(-),Sc:80.82%,Sp:52.96%; LightGBM:A:AUC值0.822(-),Sc:70.14%,Sp:80.68%; B:AUC值0.767(-),Sc:80.82%,Sp:57.33%	-

Tab.3 Bias risk assessment for the models of included literatures

纳入研究	偏倚风险				适应性评价			整体
纳入研究	研究对象	预测因子	结局	统计分析	研究对象	预测因子	结局	偏倚风险	适应性风险
Zheng等^[14]	+	+	?	-	+	+	+	-	+
Ji等^[15]	+	+	+	?	+	+	+	?	+
Yan等^[16]	+	+	?	-	+	+	+	-	+
Smith等^[17]	?	+	+	-	+	+	+	-	+
宋甜田等^[18]	+	?	?	-	+	+	+	-	+
李景余等^[19]	-	+	-	-	+	+	+	-	+
吴柯等^[20]	-	-	?	-	+	+	+	-	+
廖峻等^[21]	-	-	?	-	+	+	+	-	+
Papavasileiou等^[22]	?	+	-	-	+	+	+	-	+
吴倩等^[23]	-	-	?	-	+	+	+	-	+
Zhang等^[24]	+	+	-	-	+	+	+	-	+
王孟等^[25]	+	+	?	-	+	+	+	-	+

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