眼底OCT图像中糖尿病性黄斑水肿的分割

何锦涛, 陈明惠, 贾文宇, 等. 眼底OCT图像中糖尿病性黄斑水肿的分割[J]. 光电工程, 2018, 45(7): 170605. doi: 10.12086/oee.2018.170605
引用本文: 何锦涛, 陈明惠, 贾文宇, 等. 眼底OCT图像中糖尿病性黄斑水肿的分割[J]. 光电工程, 2018, 45(7): 170605. doi: 10.12086/oee.2018.170605
He Jintao, Chen Minghui, Jia Wenyu, et al. Segmentation of diabetic macular edema in OCT retinal images[J]. Opto-Electronic Engineering, 2018, 45(7): 170605. doi: 10.12086/oee.2018.170605
Citation: He Jintao, Chen Minghui, Jia Wenyu, et al. Segmentation of diabetic macular edema in OCT retinal images[J]. Opto-Electronic Engineering, 2018, 45(7): 170605. doi: 10.12086/oee.2018.170605

眼底OCT图像中糖尿病性黄斑水肿的分割

  • 基金项目:
    国家自然科学基金青年科学基金项目(61308115);上海市自然科学基金项目(13ZR1457900);上海市科委产学研医项目(15DZ1940400)
详细信息
    作者简介:
    通讯作者: 陈明惠(1981-),女,博士,副教授,主要从事生物医学光学等方面的研究。E-mail:cmhui.43@163.com
  • 中图分类号: R774.5;TP391.41

Segmentation of diabetic macular edema in OCT retinal images

  • Fund Project: Supported by Project supported by the National Science Foundation for Young Scientists of China (61308115), Shanghai Municipal Natural Science Foundation (13ZR1457900), and Industrial Technology and medical Research Funds of Shanghai (15DZ1940400)
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  • 糖尿病性黄斑水肿(DME)是导致成年人失明的主要原因之一,它的病理特征主要表现在视网膜内黄斑处液体的积聚。由于光学相干层析成像(OCT)具有无创性、成像安全快速等特点,在临床上被广泛用于眼科疾病的诊断。本文提出一种分割OCT图像中糖尿病性黄斑水肿的方法,首先通过对图像的预处理,排除散斑噪声和血管对最终分割结果的影响,再用改进的水平集方法有效地解决分割的问题,并计算水肿区域的面积,为后期的临床诊断治疗提供定性和定量的工具,最后将本文方法在15个患有DME成人的OCT视网膜图像上进行验证。结果表明:囊状水肿分割的精确度、灵敏度和Dice相似性系数分别为81.12%、86.90%、80.05%。

  • Overview: Diabetic macular edema (DME) is one of the important reasons leading to blindness, and the incidence of diabetic retinopathy is usually associated with macular edema symptoms. Its pathological features are mainly manifested in the accumulation of fluid in the retina. The ophthalmologist could identify and diagnosis the cystoids edema in the optical coherence tomography (OCT) image, but it is time-consuming and labor intensive. Furthermore, it is necessary to manually mark each slice of the OCT images if the ophthalmologist wants to quantify the cystic edema. Thus, an automated algorithm is proposed to enable automatic segmentation of cystoids edema and to provide an area of cystic edema in the slice to estimate the volume. The method is divided into two steps of preprocessing and segmentation. The first step, preprocessing, we should eliminate the difference in signal-to-noise of the images. A variety of reasons would result in the difference between images, such as the images come from different patients. It would also result in intensity inhomogeneity of retinal OCT images. It would also lead to intensity inhomogeneity between each layer of the retinal in the images. Therefore, it is important to eliminate these effects. To prevent the interference of blood vessels leading to false detection, we use the gamma transformation to change the brightness, which not only removes the effects of the blood vessels but also retains the characteristics of the region of interest. For speckle noise, we remove the noise effectively by the anisotropic filtering method. We eliminate the noise of the retinal OCT images as well as preserve the edge information of each layer. The second step, segmentation, we extract the cystic edema area by improved level set function. Due to the distance regularizing term, the model is no re-initialization which overcoming the shortcomings of the traditional level set function allowing for flexible initialization of level set function. Another advantage of the method is that the Gaussian kernel function reduces the sensitivity to noise. Finally, we utilize the relationship between the number of pixels and the size of the image (an image region of 0.04 mm2 contains a set of 16 pixels×52 pixels), which calculated the area of the edema area in the OCT image quantitatively. Experiment result shows that the precision, sensitivity and dice similarity coefficient (DSC) for DME segmentation are 81.12%, 86.90% and 80.05%, respectively. It can be seen that the edema area can be divided effectively. The method provides quantitative analytic tools for clinical diagnosis and therapy.

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  • 图 1  算法流程图

    Figure 1.  The flowchart of the proposed method

    图 2  滤波结果示意图

    Figure 2.  The filtered OCT B-scan image

    图 3  随机选取的眼底OCT图像的切片

    Figure 3.  Randomly selected slice of OCT images

    图 4  比较用自动分割提取的与人工分割提取的水肿面积大小

    Figure 4.  Comparison of the calculated area of liquid from the manual and the automatic algorithm

    表 1  囊样水肿分割结果客观评价

    Table 1.  Objective evaluation of segmentation results

    灵敏度/% 精确度/% Dice系数/%
    切片10 79.52 88.68 81.37
    切片24 87.26 94.52 80.44
    切片25 78.91 84.35 78.17
    切片28 80.47 86.57 77.21
    切片36 79.42 82.37 83.06
    平均值 81.12 86.90 80.05
    下载: 导出CSV

    表 2  算法效率的客观评价

    Table 2.  Objective evaluation of algorithm efficiency

    OCT图像 传统水平集/s 本文方法/s
    切片10 36.78 4.09
    切片28 43.84 5.36
    下载: 导出CSV
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出版历程
收稿日期:  2017-11-08
修回日期:  2018-03-15
刊出日期:  2018-07-01

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