Journal of Jilin University(Engineering and Technology Edition) ›› 2022, Vol. 52 ›› Issue (7): 1626-1638.doi: 10.13229/j.cnki.jdxbgxb20210652

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Transfer learning of medical image segmentation based on optimal transport feature selection

Sheng-sheng WANG1(),Lin-yan JIANG1,Yong-bo YANG2   

  1. 1.College of Computer Science and Technology,Jilin University,Changchun 130012,China
    2.Teaching Assessment Center,Air Force Aviation University,Changchun 130021,China
  • Received:2021-07-12 Online:2022-07-01 Published:2022-08-08

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Abstract:

In the unsupervised domain adaptive transfer learning process, domain-independent features lead to the degradation of model segmentation performance, but there is no effective feature selection method for transfer learning segmentation model at present. To solve this problem, a general feature selection module for transfer learning was proposed based on optimal transport, which can be applied to various unsupervised domain adaptive image segmentation models. In this module, the optimal sample subsets of two domains are selected by weighted optimal transport of segmentation accuracy, and then the features of sample subsets are subjected to entropy regularized optimal transport, so as to obtain a descending list of similarity between two domains to remove domain-independent features. The universal feature selection module is applied to three unsupervised domain adaptive models to solve the problem of Covid-19 image segmentation, which improves the model performance to a certain extent.

Key words: artificial intelligence, transfer learning, unsupervised domain adaptation, optimal transport, feature selection, image segmentation

CLC Number: 

  • TP18

Fig.1

Image segmentation transfer learning process diagram based on optimal transport universal feature selection module"

Fig.2

Flow chart of segmentation accuracy weight calculation"

Fig.3

Application of general feature selection module of optimal transfer learning in seg-jdot model"

Fig.4

Application of general feature selection module for optimal transfer learning in e-UDA model"

Fig.5

Application of universal feature selection module of optimal transfer learning in self-ensembling model"

Table 1

Segmentation index of adaptive tasks based on different sample selection methods"

特征

维度

评价指标分割准确性加权OT随机样本选择OT1OT2

512

Dice/%67.354.964.165.6
Sen/%71.971.173.171.5
Pre/%65.746.066.265.1

2048

Dice/%70.964.267.168.4
Sen/%74.872.371.273.1
Pre/%68.664.965.966.5

4096

Dice/%69.169.169.169.1
Sen/%72.772.772.772.7
Pre/%65.965.965.965.9

Table 2

Segmentation index of adaptive tasks based on different feature selection methods"

域适

应对

评价指标未进行特征选择

本文

方法

升序特征选择随机特征选择
4096↓512↑512→512

A→B

Dice/%71.572.240.160.8
Sen/%73.975.661.672.2
Pre/%71.672.832.652.1

B→A

Dice/%63.365.836.153.6
Sen/%72.571.360.370.1
Pre/%65.365.129.644.9

Fig.6

Dice curve based on different feature numbers for unadapted tasks"

Fig.7

Segmentation effect of COVID-19 CT in different patients without adaptation"

Table 3

Segmentation index based on different number of features under different domain adaptation tasks"

方 法

评价

指标

不同特征维度
↓512↓1024↓20483072
BaselineDice/%67.169.270.571.2
Sen/%71.672.174.975.8
Pre/%65.265.368.269.3
seg‐jdotDice/%74.974.876.978.1
Sen/%80.379.880.681.1
Pre/%73.175.375.376.8
e‐UDADice/%74.676.778.378.1
Sen/%78.180.179.979.6
Pre/%75.374.976.876.1
self‐ensemblingDice/%75.476.377.277.9
Sen/%79.279.479.180.2
Pre/%63.764.165.366.8

Table 4

Segmentation indicators before and after using this method under different domain adaptation tasks"

方法评价指标使用通用特征选择模块前使用通用特征选择模块后
BaselineDice/%68.971.2
Sen/%72.875.8
Pre/%65.369.3
seg‐jdotDice/%75.178.1
Sen/%80.181.1
Pre/%74.876.8
e‐UDADice/%76.378.3
Sen/%79.579.9
Pre/%75.176.8
self‐ensemblingDice/%76.777.9
Sen/%79.480.2
Pre/%64.166.8

Fig. 8

COVID-19 CT segmentation results of different patients under different domain adaptation methods"

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