Research Progress on Cardiac Segmentation in Different Modal Medical Images by Traditional Methods and Deep Learning

doi:10.11938/cjmr20233086

Abstract

Abstract:

As the aging population increases, the prevalence of cardiovascular disease rises annually. In this context, the evaluation of cardiac function using medical imaging techniques plays a pivotal role in the diagnosis and treatment of cardiovascular disease. Cardiac segmentation is a prerequisite for assessing cardiac function and has been closely studied by clinicians and scientific researchers. This paper provides a comprehensive review of the literature from the past decade on cardiac segmentation, categorizing the studies into traditional segmentation approaches and deep learning methodologies. Emphasis is placed on the detailed discussion of segmentation methods based on active contours and atlas models; deep learning algorithms based on U-Net and full convolution neural network (FCN) are also extensively discussed. In particular, this paper elaborates various approaches to enhance deep learning networks and achieve accurate segmentation of specific cardiac regions. These approaches include incorporating local modules, optimizing loss functions, and enhancing network architectures. A comprehensive summary of the aforementioned methods is presented, considering three imaging modalities: cardiac magnetic resonance imaging, computed tomography, and ultrasonic cardiogram. Lastly, the article concludes by summarizing the current research status and discussing research directions for further exploration.

Key words: cardiac image segmentation, deep learning, U-Net, FCN

CLC Number:

TP391.4

CHANG Bo, SUN Haoyun, GAO Qingyu, WANG Lijia. Research Progress on Cardiac Segmentation in Different Modal Medical Images by Traditional Methods and Deep Learning[J]. Chinese Journal of Magnetic Resonance, 2024, 41(2): 224-244.

Figures/Tables 7

Fig. 1

Fig. 2

Table 1

Table 2

Summary of segmentation networks based on CMRI images

方法	时间	学习框架	数据集	Dice系数			Hausdorff距离(HD)/mm
方法	时间	学习框架	数据集	左心室 (LV)	右心室 (RV)	心肌 (Myo)	左心室 (LV)	右心室 (RV)	心肌 (Myo)
Active contour models^[87]	2019	TensorFlow	ACDC	0.986	0.940	0.969	4.73	5.95	5.42
MSU-Net^[42]	2019	TensorFlow	ACDC	0.897	0.855	0.836	-	-	-
3D high resolution^[92]	2019	TensorFlow	1912例临床数据	0.8792	-	-	3.99	-
Dynamic pixel-wise weighting-FCN^[52]	2020	TensorFlow	MICCAI 2013	-	-	0.803	-	-	-
FCN for left ventricle segmentation^[128]	2020	-	MICCAI2009 33例临床数据	0.95	-	0.914	-	-	-
CNN incorporating domain-specific constraints^[38]	2020	TensorFlow	ACDC	0.959	0.924	0.873	-	-	-
Combined CNN and U-net^[50]	2020	PyTorch	MICCAI2009	0.951	-	-	3.641	-	-
Automatic segmentation and quantification^[46]	2020	PyTorch	ACDC、临床数据	0.96	-	0.88	6.31	-	7.11
Fully automatic segmentation of RV and LV^[88]	2020	PyTorch	ACDC、5570例临床数据	0.927	0.873	-	-	-	-
Deep CNN^[41]	2020	TensorFlow	MICCAI2009	0.961	0.949	0.867	-	-	-
DMU-net^[43]	2020	Keras	71例临床数据	-	-	-	-	4.445	-
Semi-supervised^[47]	2021	PyTorch	M&Ms	0.909	0.879	0.845	9.42	12.65	11.85
Active contour models^[82]	2021	-	ACDC、LVQuan18	0.890 0.805	-	-	12.247 19.717	-	-
Deep reinforcement learning^[53]	2021	-	ACDC、 Sunnybrook2009	0.9502 0.9351	-	-	-	-	-
Attention guided U-Net^[39]	2021	TensorFlow	LVSC	-	-	0.956	-	-	1.456
Dens FCN^[36]	2021	TensorFlow	210例临床数据	0.944	0.908	0.851	7.2	7.35	5.9
SegNet^[85]	2022	TensorFlow	1354例临床数据	0.878	-	-	10.163	-	-
FCN^[51]	2022	-	150例临床数据	0.930	-	-	-	-	-
Cascade approach structures^[49]	2022	TensorFlow	ACDC	0.963	0.900	0.894	8.062	14.660	7.906
DEU-Net2.0^[40]	2022	PyTorch	ACDC	0.970	0.949	0.904	7.0	12.2	9.0
RNN with Atrous Spatial pyramid pooling^[86]	2022	PyTorch	56例临床数据	-	-	0.8543	-	-	-
OSFNet^[90]	2022	TensorFlow	ACDC	0.946	-	-	3.976	-	-
Deep Atlas network^[44]	2023	TensorFlow	71例临床数据	-	0.902	-	-	4.358	-

Table 2

Table 3

Summary of different segmentation networks based on cardiac CT images

方法	时间	学习框架	数据集	Dice系数				Hausdorff距离(HD)/mm
方法	时间	学习框架	数据集	左心室 (LV)	右心室 (RV)		心肌 (Myo)	左心室 (LV)		右心室 (RV)	心肌 (Myo)
CNN^[93]	2016	-	60例临床病例	0.85	-		-	-		-	-
Combining faster R-CNN and U-net^[54]	2018	PyTorch	MM-WHS2017	0.879	0.902		0.822	-		-	-
CNN^[102]	2018	TensorFlow	11例临床病例	0.878	0.829		-	-		-	-
Hybrid loss guided CNN^[65]	2018	TensorFlow	MM-WHS2017	0.8680	0.7143		0.665	-		-	-
CNN and anatomical label configurations^[94]	2018	Caffe	MM-WHS2017	0.918	0.909		0.881	-		-	-
3D deeply-supervised U-Net^[55]	2018	-	MM-WHS2017	0.893	0.810		0.837	-		-	-
DL and shape context^[59]	2018	Keras	MM-WHS2017	0.935	0.825		0.879	-		-	-
Multi-planar deep segmentation networks^[99]	2018	TensorFlow	MM-WHS2017	0.904	0.883		0.851	-		-	-
3D CNN^[103]	2018	TensorFlow	MM-WHS2017	0.923	0.857		0.856	-		-	-
Two-stage 3D U-net^[56]	2018	TensorFlow	MM-WHS2017	0.800	0.786		0.729	-		-	-
Multi-depth fusion network^[58]	2019	TensorFlow	MICCAI 2017全心 CT数据集	0.944	0.895		0.889	-		-	-
3D deeply supervised attention U-net^[57]	2020	MATLAB	100例临床病例	0.916	-		-	6.840		-	-
DL^[66]	2020	-	1100例临床数据	-		-	0.883	-	-		13.4
Unet-GAN^[98]	2021	PyTorch	MM-WHS2017	整体平均0.889
Multiple GAN guided by Self-attention mechanism^[97]	2021	-	MM-WHS2017	0.814		-	0.669	-	-		-
AttU_Net_conv1_5Mffp^[62]	2021	PyTorch	MM-WHS2017	0.907		0.842	0.906	-	-		-
PC-Unet^[60]	2021	-	20例临床数据	0.885		-	-	7.05	-		-
Computer graphics imaging and DL^[129]	2022	-	130例临床数据	-		0.81~0.95	-	-	-		-
DRLSE^[25]	2022	-	5例临床数据	0.9253		-	-	7.874	-		-
4D contrast-enhanced^[104]	2022	PyTorch	1509例临床数据	整体平均0.8				-	-		-
MRDFF^[95]	2022	-	MM-WHS2017	0.899		0.823	-	-	-		-
Transnunet^[64]	2022	-	MM-WHS2017	0.921		-	-	-	-		-
Self-attention mechanism^[45]	2023	TensorFlow	96例临床病例	-		-	0.9202	-	-		-

Table 3

Table 4

Table 5

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文献	方法	分割部位
Ngo等^[79]	水平集+DL	LV
Avendi等^[80]	可变形模型+DL	LV
Dong等^[81]	可变形模型+DL	LV
Du等^[82]	ACM+DL	LA