基于经会阴三维超声联合剪切波弹性成像的肛提肌形态及弹性对女性压力性尿失禁诊断模型的构建及效果评价

doi:10.3969/j.issn.1006-5725.2025.08.020

摘要/Abstract

摘要：

目的探讨肛提肌形态及弹性与压力性尿失禁（SUI）之间的关系；同时建立基于肛提肌形态及弹性指标的SUI多模态诊断模型并评价模型的诊断效果。方法选取2020年9月至2022年9月于华北理工大学附属医院就诊的SUI女性患者147例为SUI组（病例组），同期选取排除SUI的女性144例为非SUI组（对照组），行经会阴超声检查，测量静息状态下肛提裂孔前后径（LH-A1）、肛提裂孔横径（LH-D1）、肛提裂孔面积（LA1）；最大瓦式动作下肛提裂孔前后径（LH-A2）、肛提裂孔横径（LH-D2）、肛提裂孔面积（LA2）；记录缩肛状态下肛提肌损伤情况（LA-MI）；经会阴SWE检查并记录：静息及缩肛状态下耻骨直肠肌弹性模量值（E1、E3）。比较各组超声参数的差异，应用logistic回归模型进行多因素分析，并以此建立SUI的诊断模型。通过Hosmer-Lemeshow统计量对logistic回归模型的拟合优度进行检验，ROC曲线评价各单独指标及诊断模型对压力性尿失禁的诊断效能，决策曲线评价模型的临床效用。结果两组比较，年龄、BMI、LH-A1、LH-D1、LA1、LH-A2、LH-D2、LA2、LA-MI、E1及E3差异有统计学意义（P < 0.05）。多因素logistic回归分析表明，年龄、BMI、LH-A1、LA2、LA-MI、E1及E3与SUI有关联（P < 0.05）。据此构建SUI的诊断模型：PRESUI = 0.261 × 年龄 + 0.904 × BMI-4.300 × LH-A1 + 1.166 × LA2-2.815 × LA-MI + 0.587 × E1-0.631 × E3-1.258。该模型拟合优度好（P = 0.983）。ROC曲线结果显示，年龄、BMI、LH-A1、LA2、LA-MI、E1及E3均具有诊断SUI的效能（AUC > 0.500，P < 0.05）；构建的诊断模型诊断SUI的AUC为0.996（95%CI：0.992~1.000），诊断效能大于各单独指标。当诊断模型的截断值为0.437时，灵敏度为98.0%、特异度为97.2%。决策曲线显示在阈值0.1 ~ 1.0的范围内，诊断模型的临床净获益良好。结论 SUI女性的肛提肌形态与弹性均有所改变；SWE技术具有潜在的应用价值，可用于定量评估尿道周围肌肉（LAM）的弹性；以年龄、BMI、LH-A1、LA2、LA-MI、E1及E3构建的诊断模型具有较高的临床应用价值。

关键词: 三维超声, 剪切波弹性成像, 肛提肌, 压力性尿失禁

Abstract:

Objective To investigate the relationship between the morphology and elasticity of the levator ani muscle （LAM） and stress urinary incontinence （SUI）， and to develop a multimodal diagnostic model for SUI based on LAM morphology and elasticity parameters， while evaluating the diagnostic performance of this model. Methods From September 2020 to September 2022， 147 female patients with SUI from the Affiliated Hospital of North China University of Science and Technology were enrolled as the SUI group （case group）， while 144 women without SUI during the same period were selected as the non-SUI group （control group）. Transperineal ultrasonography was conducted to measure the anteroposterior diameter （LH-A1） and transverse diameter （LH-D1） of the levator hiatus at rest， the resting area of the levator hiatus （LA1）， as well as the anteroposterior diameter （LH-A2）， transverse diameter （LH-D2）， and area （LA2） of the levator hiatus during the maximum Valsalva maneuver. Additionally， ultrasonography was used to observe LAM injury （LA-MI） during pelvic muscle contraction. Shear wave elastography （SWE） was also performed transperineally to record the elastic modulus values of the puborectalis muscle at rest （E1） and during pelvic muscle contraction （E3）. The differences in ultrasound parameters between the two groups were compared， and a logistic regression model was constructed for multivariate analysis to establish a diagnostic model for SUI. The goodness of fit of the logistic regression model was assessed using the Hosmer-Lemeshow test. The diagnostic performance of individual indicators and the diagnostic model for SUI was evaluated using the receiver operating characteristic （ROC） curve. Finally， the clinical utility of the model was assessed using decision curve analysis. Results There were statistically significant differences in age， BMI， LH-A1， LH-D1， LA1， LH-A2， LH-D2， LA2， LA-MI， E1， and E3 between the two groups （P < 0.05）. Multivariate logistic regression analysis revealed that age， BMI， LH-A1， LA2， LA-MI， E1， and E3 were significantly associated with SUI （P < 0.05）. Based on these findings， a diagnostic model for SUI was established： PRESUI = 0.261 × age + 0.904 × BMI-4.300 × LH-A1 + 1.166 × LA2-2.815 × LA-MI + 0.587 × E1-0.631 × E3-1.258. The model demonstrated excellent goodness-of-fit （P = 0.983）. The ROC curve analysis indicated that age， BMI， LH-A1， LA2， LA-MI， E1， and E3 all exhibited diagnostic efficacy for SUI （AUC > 0.500， P < 0.05）. Notably， the AUC of the constructed diagnostic model for SUI was 0.996 （95%CI： 0.992 ~ 1.000）， suggesting that the diagnostic accuracy of the model surpassed that of individual indicators. When the cut-off value of the diagnostic model was set at 0.437， the sensitivity reached 98.0%， and the specificity was 97.2%. Furthermore， the decision curve analysis demonstrated that the diagnostic model provided substantial net clinical benefit within the threshold probability range of 0.1 to 1.0. Conclusions The morphology and elasticity of the LAM are significantly altered in women with SUI. The SWE technique demonstrates potential application value for quantitatively assessing the elasticity of the LAM. Furthermore， the diagnostic model constructed based on age， BMI， LH-A1， LA2， LA-MI， E1， and E3 exhibits high clinical application value.

Key words: three-dimensional ultrasound, shear wave elastography, levator ani muscle, stress urinary incontinence

中图分类号:

R445.1

郭二芳,冯蕾,石超会,李宁,林伟群,张树华. 基于经会阴三维超声联合剪切波弹性成像的肛提肌形态及弹性对女性压力性尿失禁诊断模型的构建及效果评价[J]. 实用医学杂志, 2025, 41(8): 1224-1231.

Erfang GUO,Lei FENG,Chaohui SHI,Ning LI,Weiqun LIN,Shuhua. ZHANG. Construction and evaluation of a diagnostic model for female stress urinary incontinence based on the morphology and elasticity of the levator ani muscle by transperineal three⁃dimensional ultrasound combined with shear wave elastography[J]. The Journal of Practical Medicine, 2025, 41(8): 1224-1231.

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组别	例数	年龄（x ± s）/岁	BMI（x ± s）/（kg/m²）	孕次	产次
非SUI组	144	49.12 ± 6.18	23.09 ± 2.86	2（1，3）	1（1，2）
SUI组	147	59.88 ± 9.18	27.00 ± 3.03	2（1，3）	1（1，2）
t/Z值 P值		11.740	11.263	-1.752	-0.819
t/Z值 P值		0.000	0.000	0.080	0.413

项目	非SUI组（n = 144）	SUI组（n = 147）	t/χ² 值	P值
LH-A1/cm	5.03 ± 0.54	5.51 ± 0.64	6.846	< 0.001
LH-D1/cm	3.53 ± 0.23	3.88 ± 0.48	8.031	< 0.001
LA1/cm²	13.65 ± 2.31	16.93 ± 3.28	9.863	< 0.001
LH-A2/cm	5.48 ± 0.65	6.11 ± 0.83	7.153	< 0.001
LH-D2/cm	3.91 ± 0.35	4.43 ± 0.54	9.593	< 0.001
LA2/cm²	15.81 ± 2.45	23.18 ± 5.69	14.390	< 0.001
LA-MI	12/144	34/147	11.966	0.001
E1/kPa	18.89 ± 3.38	25.88 ± 6.07	12.146	< 0.001
E3/kPa	60.20 ± 7.99	48.17 ± 6.19	14.318	< 0.001

变量	B	SE	Beta	t值	P值	容差	VIF
常量	-0.346	0.308	-	-1.123	0.263	-	-
年龄	0.008	0.002	0.150	3.904	< 0.001	0.636	1.573
BMI	0.029	0.005	0.207	5.652	< 0.001	0.705	1.419
LH-A1	-0.087	0.051	-0.112	-1.723	0.086	0.222	4.495
LH-D1	0.144	0.074	0.121	1.948	0.052	0.246	4.060
LA1	0.025	0.011	0.165	2.282	0.023	0.180	5.546
LH-A2	-0.041	0.043	-0.067	-0.970	0.333	0.197	5.067
LH-D2	-0.095	0.061	-0.100	-1.542	0.124	0.224	4.463
LA2	0.020	0.005	0.224	3.610	< 0.001	0.245	4.077
LA-MI	-0.051	0.045	-0.037	-1.136	0.257	0.892	1.121
E1	0.023	0.003	0.276	7.847	< 0.001	0.765	1.307
E3	-0.017	0.002	-0.324	-8.946	< 0.001	0.718	1.393

变量	β	SE	Wald χ²	P值	OR	95%CI
常量	-1.258	9.581	0.017	0.895	0.284	-
年龄	0.261	0.083	9.828	0.002	1.298	1.103 ~ 1.527
BMI	0.904	0.249	13.142	< 0.001	2.469	1.515 ~ 4.025
LH-A1	-4.300	1.365	9.919	0.002	0.014	0.001 ~ 0.197
LH-D1	1.053	2.013	0.274	0.610	2.866	0.055 ~ 148.180
LH-D2	-2.997	1.788	2.810	0.094	0.050	0.002 ~ 1.660
LA2	1.166	0.341	11.714	0.001	3.210	1.646 ~ 6.261
LA-MI	-2.815	1.367	4.242	0.039	0.060	0.004 ~ 0.873
E1	0.587	0.168	12.154	< 0.001	1.799	1.293 ~ 2.502
E3	-0.631	0.183	11.874	0.001	0.532	0.372 ~ 0.762

临床及超声指标	AUC	P值	95%CI	截断值	灵敏度/%	特异度/%	Kappa
年龄/岁	0.823	< 0.001	0.777～0.869	54.5	69.4	79.2	0.486
BMI/（kg/m²）	0.814	< 0.001	0.767～0.861	24.95	73.5	72.9	0.464
LH-A1/cm	0.706	< 0.001	0.647～0.765	5.285	66.7	70.1	0.368
LA2/cm²	0.867	< 0.001	0.826～0.909	20.125	68.7	98.6	0.673
LA-MI	0.574	< 0.001	0.508～0.640	-	-	-	-
E1/kPa	0.836	< 0.001	0.790～0.882	23.9	63.3	91.7	0.550
E3/kPa	0.884	< 0.001	0.848～0.921	54.35	86.4	73.6	0.600
预测模型	0.996	< 0.001	0.992～1.000	0.437	98.0	97.2	0.952