医学图像分割之肝脏分割(2D)

文章目录

肝脏分割数据集

肝脏分割分割主要有三个开源数据集:LiTS17,Sliver07,3DIRCADb

LiTS17包含131个数据,可以用于肝脏及肿瘤的分割

Sliver07包含20个数据,但仅仅包含肝脏,并没有肿瘤的金标准

3DIRCADb包含20个数据,可以用于肝脏及肿瘤的分割

医学图像分割之肝脏分割(2D)医学图像分割之肝脏分割(2D)医学图像分割之肝脏分割(2D)

提示:以下是本篇文章正文内容,下面案例可供参考

一、预处理

这三个肝脏分割数据集都是3D数据,所以如过要进行训练必须要对数据进行切片。

对3D nii文件进行调窗,找到肝脏区域并向外扩张,将数据z轴的spacing调整到1mm。

将3D nii格式的数据切片为2D png格式。

 # 将灰度值在阈值之外的截断掉
 # upper = 200
 # lower = -200
 ct_array[ct_array > para.upper] = para.upper
 ct_array[ct_array < para.lower] = para.lower
 #肝脏分割设置
 seg_array[seg_array > 0] = 1
 # 找到肝脏区域开始和结束的slice,并各向外扩张
 z = np.any(seg_array, axis=(1, 2))
 start_slice, end_slice = np.where(z)[0][[0, -1]]

# 对CT数据在横断面上进行降采样(下采样),并进行重采样,将所有数据的z轴的spacing调整到1mm
ct_array = ndimage.zoom(ct_array,(ct.GetSpacing()[-1] / para.slice_thickness, para.down_scale, para.down_scale),order=3)
seg_array = ndimage.zoom(seg_array, (ct.GetSpacing()[-1] / para.slice_thickness, para.down_scale, para.down_scale), order=0)




#进行切片操作
 for i in range(volume.shape[0]):
        slice = volume[i,:,:]
        slice_post = WL(slice, WC, WW)
        slice_post = slice_post.astype(np.uint8)

        # slice_post = cv.equalizeHist(slice_post)
        slices_in_order.append(slice_post)

医学图像分割之肝脏分割(2D)医学图像分割之肝脏分割(2D)

                                            原始CT                                            调窗后

二、图像增强

同时对肝脏的 Original CT,Ground Truth进行图像增强。

# 图像旋转: 按照概率0.8执行,最大左旋角度10,最大右旋角度10
# p.rotate(probability=0.5, max_left_rotation=20, max_right_rotation=20)

# 图像左右互换: 按照概率0.5执行
# p.flip_left_right(probability=0.8)

# # # 图像放大缩小: 按照概率0.8执行,面积为原始图0.85倍
# p.zoom_random(probability=1, percentage_area=0.8)

 

三、训练

1.模型搭建

import torch.nn as nn
import torch
from torch import autograd


class DoubleConv(nn.Module):
    def __init__(self, in_ch, out_ch):
        super(DoubleConv, self).__init__()
        self.conv = nn.Sequential(
            nn.Conv2d(in_ch, out_ch, 3, padding=1),
            nn.BatchNorm2d(out_ch),
            nn.ReLU(inplace=True),
            nn.Conv2d(out_ch, out_ch, 3, padding=1),
            nn.BatchNorm2d(out_ch),
            nn.ReLU(inplace=True)
        )

    def forward(self, input):

        return self.conv(input)


class UNet(nn.Module):
    def __init__(self, in_ch, out_ch):
        super(UNet, self).__init__()

        self.conv1 = DoubleConv(in_ch, 64)
        self.pool1 = nn.MaxPool2d(2)
        self.conv2 = DoubleConv(64, 128)
        self.pool2 = nn.MaxPool2d(2)
        self.conv3 = DoubleConv(128, 256)
        self.pool3 = nn.MaxPool2d(2)
        self.conv4 = DoubleConv(256, 512)
        self.pool4 = nn.MaxPool2d(2)
        self.conv5 = DoubleConv(512, 1024)
        self.up6 = nn.ConvTranspose2d(1024, 512, 2, stride=2)
        self.conv6 = DoubleConv(1024, 512)
        self.up7 = nn.ConvTranspose2d(512, 256, 2, stride=2)
        self.conv7 = DoubleConv(512, 256)
        self.up8 = nn.ConvTranspose2d(256, 128, 2, stride=2)
        self.conv8 = DoubleConv(256, 128)
        self.up9 = nn.ConvTranspose2d(128, 64, 2, stride=2)
        self.conv9 = DoubleConv(128, 64)
        self.conv10 = nn.Conv2d(64, out_ch, 1)

    def forward(self, x):
        c1 = self.conv1(x)
        p1 = self.pool1(c1)
        c2 = self.conv2(p1)
        p2 = self.pool2(c2)
        c3 = self.conv3(p2)
        p3 = self.pool3(c3)
        c4 = self.conv4(p3)
        p4 = self.pool4(c4)
        c5 = self.conv5(p4)
        up_6 = self.up6(c5)
        merge6 = torch.cat([up_6, c4], dim=1)
        c6 = self.conv6(merge6)
        up_7 = self.up7(c6)
        merge7 = torch.cat([up_7, c3], dim=1)
        c7 = self.conv7(merge7)
        up_8 = self.up8(c7)
        merge8 = torch.cat([up_8, c2], dim=1)
        c8 = self.conv8(merge8)
        up_9 = self.up9(c8)
        merge9 = torch.cat([up_9, c1], dim=1)
        c9 = self.conv9(merge9)
        c10 = self.conv10(c9)
        out = nn.Sigmoid()(c10)
        return out

2.模型训练

if __name__ == '__main__':
    device = torch.device("cuda" if torch.cuda.is_available() else "cpu")

    LEARNING_RATE = 1e-3
    LR_DECAY_STEP = 2
    LR_DECAY_FACTOR = 0.5
    WEIGHT_DECAY = 5e-4
    BATCH_SIZE = 1
    MAX_EPOCHS = 2
    model = UNet()
    criterion = DiceLoss()
    if opt.use_gpu:
        criterion = criterion.cuda(opt.device)
    lr = opt.lr
    optimizer = torch.optim.Adam(model.parameters(), lr=lr, weight_decay=opt.weight_decay)
    lr_scheduler = torch.optim.lr_scheduler.ExponentialLR(optimizer, opt.lr_decay)

    
    MODEL = Unet(out_ch=2)

    OPTIMIZER = torch.optim.Adam(MODEL.parameters(), lr=LEARNING_RATE, weight_decay=WEIGHT_DECAY)
    LR_SCHEDULER = torch.optim.lr_scheduler.StepLR(OPTIMIZER, step_size=LR_DECAY_STEP, gamma=LR_DECAY_FACTOR)

    CRITERION = DiceLoss().to(device)

四、测试

    for i in range(1, 10):
      
        idx_list.append(i)
        ct = sitk.ReadImage(data_path + 'volume-' + str(i) + '.nii',sitk.sitkInt16)
        seg = sitk.ReadImage(data_path + 'segmentation-' + str(i) + '.nii',sitk.sitkInt16)
        predictions_in_order = []

        for slice in slices_in_order:
            slice = torch.from_numpy(slice).float() / 255.
            output = model(slice.unsqueeze(0).unsqueeze(0))
            prediction = sm(output)
            _, prediction = torch.max(prediction, dim=1) #返回每一行中最大值的那个元素,且返回其索引(返回最大元素在这一行的列索引)
            prediction = prediction.squeeze(0).cpu().detach().numpy().astype(np.uint8)
            predictions_in_order.append(prediction)

测试结果可视化:

医学图像分割之肝脏分割(2D)

医学图像分割之肝脏分割(2D)医学图像分割之肝脏分割(2D)

总结

第一次写,也是随手一写,后续会更新3D肝脏分割,2.5D肝脏分割,以及肝脏肿瘤分割。

文章出处登录后可见!

已经登录?立即刷新

共计人评分,平均

到目前为止还没有投票!成为第一位评论此文章。

(1)
xiaoxingxing的头像xiaoxingxing管理团队
上一篇 2022年6月1日 上午11:17
下一篇 2022年6月1日 上午11:19

相关推荐