基于从头训练模式深度学习卷积神经网络模型评估急性肺栓塞的价值

doi:10.3969/j.issn.1006-5725.2023.22.021

Abstract

Abstract:

Objective This research aimed to study the values of the deep learning convolutional neural network model trained from scratch（DL?CNN（fs）） in assessment of acute pulmonary thromboembolism （APE）. Methods A total of 214 patients with suspected APE who underwent computed tomography pulmonary angiography（CTPA） were retrospectively studied， including 137 patients with APE and 77 patients without APE. The presence or absence of APE was determined by the radiologists based on CTPA. The Qanadli score， Mastora score and other parameters on CTPA were measured by the radiologists. The clot volumes and distribution were measured by U?net model which was based on DL?CNN. The performance of DL?CNN（fs） in measuring clot distribution and clot burden was evaluated. The correlation between clot burden and Qanadli score， Mastora score and other CTPA parameters was calculated. Results Sensitivity， specificity and AUC of the central pulmonary artery clot distribution measured by DL?CNN（fs） were 100%， 16.8%， AUC = 0.584 （95%CI： 0.508 ~ 0.661）. Sensitivity， specificity and AUC of the peripheral pulmonary artery clot distribution were high （R1?R9， 60.8% ~ 95.2%，67.9% ~ 87.1%，0.740 ~ 0.844； L1?L10， 64.6% ~ 93.4%， 62.7% ~ 83.1%， 0.732 ~ 0.791）. Strong positive correlation was noted between clot volumes measured by DL?CNN （fs） model and Qanadli score （r = 0.867，P < 0.001）， as well as Mastora score （r = 0.854， P < 0.001）. Clot volumes measured by DL?CNN （fs） model were correlated with the right ventricular functional parameters（right ventricular diameter/left ventricular diameter， right ventricular area/left ventricular area，r = 0.549， 0.559， P < 0.01）. Conclusion The DL?CNN （fs） model has high value in detecting peripheral pulmonary embolism， and its diagnostic specificity for central pulmonary embolism needs to be further improved. The clot volumes from DL?CNN（fs） were correlated with metrics of pulmonary embolism and right ventricular function， which may help doctors to quickly evaluate the clot burden and risk stratification of acute pulmonary thromboembolism.

Key words: deep learning, convolution neural network, acute pulmonary thromboembolism, computed tomography pulmonary angiography

CLC Number:

R445.3

Runcai GUO,Lei WANG,Zhenguo HUANG,Linfeng XI,Shuai ZHANG,Min. LIU. Deep learning convolutional neural network model trained from scratch algorithm in the evaluation of acute pulmonary thromboembolism[J]. The Journal of Practical Medicine, 2023, 39(22): 2979-2983.

Figures/Tables 4

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References 20

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		10年放射科医师		χ²值	P值
		+	-	χ²值	P值
DL-CNN（fs）	+	107	89	19.653	< 0.001
	-	0	18	19.653	< 0.001

肺栓塞分布	敏感度（%）	特异度（%）	AUC	95%CI	P值
中心肺动脉	100	16.80	0.584	0.508 ~ 0.661	0.033
外周肺动脉
R1	86.50	76.40	0.815	0.753 ~ 0.876	< 0.001
R2	77.10	73.20	0.752	0.684 ~ 0.820	< 0.001
R3	82.90	82.10	0.814	0.750 ~ 0.877	< 0.001
R4	87.50	67.90	0.777	0.713 ~ 0.841	< 0.001
R5	84.50	76.90	0.807	0.744 ~ 0.870	< 0.001
R6	86.20	77.20	0.817	0.754 ~ 0.879	< 0.001
R7	95.20	73.50	0.844	0.790 ~ 0.898	< 0.001
R8	60.80	87.10	0.740	0.665 ~ 0.815	< 0.001
R9	87.10	76.40	0.818	0.756 ~ 0.879	< 0.001
R10	0	100	0.500	0.420 ~ 0.580	1
L1+3	75.00	79.50	0.772	0.702 ~ 0.843	< 0.001
L2	83.90	73.70	0.788	0.721 ~ 0.855	< 0.001
L4	64.60	81.90	0.732	0.655 ~ 0.810	< 0.001
L5	93.40	62.70	0.781	0.718 ~ 0.844	< 0.001
L6	75.40	77.70	0.766	0.619 ~ 0.841	< 0.001
L7+8	77.60	74.40	0.760	0.693 ~ 0.828	< 0.001
L9	75.00	83.10	0.791	0.718 ~ 0.863	< 0.001
L10	85.70	65.30	0.755	0.687 ~ 0.823	< 0.001

血栓负荷及心血管参数	DL-CNN（fs）
血栓负荷及心血管参数	r值	P值
Mastora score	0.854	< 0.001
Qanadli score	0.867	< 0.001
主肺动脉直径（cm）	0.308	< 0.001
升主动脉直径（cm）	-0.113	0.100
主肺动脉/升主动脉直径比	0.377	< 0.001
右/左心室最大横径比	0.549	< 0.001
右/左心室最大面积比	0.559	< 0.001
上腔静脉面积（cm²）	0.118	0.086
下腔静脉面积（cm²）	0.446	< 0.001
右室壁舒张期厚度（cm）	-0.101	0.139
室间隔舒张期厚度（cm）	-0.047	0.491
脊柱室间隔角（°）	0.406	< 0.001

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Deep learning convolutional neural network model trained from scratch algorithm in the evaluation of acute pulmonary thromboembolism

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