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ORIGINAL RESEARCH article

Front. Neuroinform., 31 August 2022

Application value of a deep learning method based on a 3D V-Net convolutional neural network in the recognition and segmentation of the auditory ossicles

\r\nXing-Rui Wang&#x;Xing-Rui Wang1†Xi Ma&#x;Xi Ma1†Liu-Xu JinLiu-Xu Jin1Yan-Jun GaoYan-Jun Gao1Yong-Jie XueYong-Jie Xue1Jing-Long LiJing-Long Li1Wei-Xian BaiWei-Xian Bai1Miao-Fei HanMiao-Fei Han2Qing ZhouQing Zhou2Feng ShiFeng Shi2Jing Wang*Jing Wang3*
  • 1Xi’an Key Laboratory of Cardiovascular and Cerebrovascular Diseases, Xi’an No.3 Hospital, Affiliated Hospital of Northwest University, Xi’an, China
  • 2Department of Research and Development, Shanghai United Imaging Intelligence Co., Ltd., Shanghai, China
  • 3Department of Medical Imaging, Xi’an Hospital of Traditional Chinese Medicine, Xi’an, China

Objective: To explore the feasibility of a deep learning three-dimensional (3D) V-Net convolutional neural network to construct high-resolution computed tomography (HRCT)-based auditory ossicle structure recognition and segmentation models.

Methods: The temporal bone HRCT images of 158 patients were collected retrospectively, and the malleus, incus, and stapes were manually segmented. The 3D V-Net and U-Net convolutional neural networks were selected as the deep learning methods for segmenting the auditory ossicles. The temporal bone images were randomized into a training set (126 cases), a test set (16 cases), and a validation set (16 cases). Taking the results of manual segmentation as a control, the segmentation results of each model were compared.

Results: The Dice similarity coefficients (DSCs) of the malleus, incus, and stapes, which were automatically segmented with a 3D V-Net convolutional neural network and manually segmented from the HRCT images, were 0.920 ± 0.014, 0.925 ± 0.014, and 0.835 ± 0.035, respectively. The average surface distance (ASD) was 0.257 ± 0.054, 0.236 ± 0.047, and 0.258 ± 0.077, respectively. The Hausdorff distance (HD) 95 was 1.016 ± 0.080, 1.000 ± 0.000, and 1.027 ± 0.102, respectively. The DSCs of the malleus, incus, and stapes, which were automatically segmented using the 3D U-Net convolutional neural network and manually segmented from the HRCT images, were 0.876 ± 0.025, 0.889 ± 0.023, and 0.758 ± 0.044, respectively. The ASD was 0.439 ± 0.208, 0.361 ± 0.077, and 0.433 ± 0.108, respectively. The HD 95 was 1.361 ± 0.872, 1.174 ± 0.350, and 1.455 ± 0.618, respectively. As these results demonstrated, there was a statistically significant difference between the two groups (P < 0.001).

Conclusion: The 3D V-Net convolutional neural network yielded automatic recognition and segmentation of the auditory ossicles and produced similar accuracy to manual segmentation results.

Introduction

Hearing impairment caused by lesions of the auditory ossicles is a common clinical disease, and both the destruction of the auditory ossicles caused by inflammation and tumors and malformation or dysplasia of the auditory ossicles can lead to hearing impairments, and even to hearing loss (Juliano et al., 2013, 2015). The ossicle chain, which comprised the three auditory ossicles (the malleus, incus, and stapes), acts as a mechanism for conducting sound in the middle ear (Figure 1). As its structure is small and fine, it can be difficult for clinicians to find abnormal auditory ossicles by physical means, making an auditory ossicle reconstruction operation difficult and requiring high-risk technology. However, accurate auditory ossicle evaluation is important for the diagnosis and pre-treatment evaluation of patients with hearing impairment. Therefore, it is critical to correctly master the anatomy of deformed auditory ossicles to formulate a surgery plan.

FIGURE 1
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Figure 1. An anatomical illustration of auditory ossicles located in the middle ear, including the malleus, incus, and stapes.

High-resolution computed tomography (HRCT) of the temporal bone can achieve submillimeter resolution and is the established standard for the clinical detection of anatomical abnormalities of the temporal bone in patients with ear disease (Jäger et al., 2005). In addition to clarifying the location and degree of the lesions, it can play a decisive role in evaluating illnesses, such as auditory ossicle malformation, trauma, inflammation, and temporal bone tumor; it can also provide a reliable basis for understanding the location and scope of the lesions, selecting surgery methods, and improving the safety of these methods (Tatlipinar et al., 2012).

The morphological characteristics of the auditory ossicles are accurately displayed by HRCT. However, the structure of the auditory ossicles is quite small; the total length of an adult stapes is approximately 3 mm (Noussios et al., 2016). In addition, not all parts of the auditory ossicles can be displayed on the same level in conventional transverse axial CT images. It can thus be challenging to accurately evaluate them using conventional axial images.

In clinical practice, the entire image can be displayed only after post-processing reconstruction of a curved planar reconstruction (CPR), multiplanar reformation (MPR), and volume rendering (VR). This post-processing reconstruction process is time-consuming and requires a higher level of expertise and experience from ear, nose, and throat (ENT) radiologists, which may result in reduced work efficiency and an increase in missed diagnoses or misdiagnoses.

With the maturity of computer-aided diagnosis technology, medical imaging artificial intelligence (AI)-aided diagnosis equipment has been widely used to study several organ structures (e.g., the lung, liver, breast, and bone) (Hosny et al., 2018). As an important branch of AI, deep learning technology, which has made significant progress since 2012, has been widely used in image classification (He et al., 2020), lesion detection, and segmentation (Ren et al., 2017; Falk et al., 2019). In some respects, it has reached or exceeded the diagnostic level of clinicians, as is the case in the diagnosis and prognosis evaluation of hepatobiliary malignant tumors (Ibragimov et al., 2018; Zhou et al., 2019), the early diagnosis and pathological classification prediction of lung cancer (Coudray et al., 2018), the establishment of a breast cancer diagnosis model to predict malignant breast cancer (Li, 2021), and the automatic detection of fundus images identifying glaucoma and diabetic retinopathy (Schmidt-Erfurth et al., 2018; Ting et al., 2019).

Despite these technological advancements, few mature studies exist on the AI-aided diagnosis of smaller structures, e.g., the auditory ossicles. This study aims to explore a computer segmentation and recognition technology of auditory ossicles, based on HRCT images, which could assist radiologists in making more accurate evaluations and diagnoses of potential auditory ossicle abnormalities, such as destruction, absence, malformation, or dysplasia.

Materials and methods

Data and structure labeling

The 158 samples used in this study were from adult patients (aged older than 18 years, mean age, 38.60 ± 18.05), who underwent temporal bone CT scanning in Xi’an Central Hospital and Xi’an No.3 Hospital from 2015 to 2019. Senior ENT radiologists confirmed the absence of any structural abnormalities of the external ear, middle ear, or inner ear from the samples provided. A Philips Brilliance iCT 256 was used for scanning using the following settings: scanning parameters, 120 kV, 200 mAs; rotation speed 0.4 s/360°; collimation, 0.625 mm; field of view, 250 mm × 250 mm; reconstruction matrix, 1024 × 1024; reconstruction interval, 0.2–0.3 mm; bone algorithm reconstruction. All scans were made from the lower edge of the external auditory canals to the upper edge of the petrous bones, with a scanning length of 1.5 cm. The samples were divided into three groups as follows: 80% were randomly selected from the data set as the training set, including the CT data of 126 cases of unilateral normal temporal bone images; 10% were selected as the test set, including the CT data of 16 cases of unilateral normal temporal bone images; 10% were selected as the validation set, including the CT data of 16 cases of unilateral normal temporal bone images.

Manual labeling of the auditory ossicle structure was conducted as follows: the original DICOM data of the HRCT images of the temporal bones were imported into ITK-SNAP 3.2, and the malleus, incus, and stapes were manually labeled under the “bone” window. The labeling process was performed by two ENT radiologists. One radiologist completed the specific segmentation and the second performed the review.

Method

Model establishment and implementation of the deep learning method

The neural network applied in this study was constructed as follows: two cascaded neural networks (from low to high resolution) were adopted as shown in Figure 2. The network structure was combined with the bottleneck structure, based on the V-Net backbone. Due to using the bottleneck structure, the network was labeled a VB-Net (“B” denoting “bottleneck”), which reduced the network parameters and increased the network depth. As shown in Figure 2, the VB-Net comprised one input block, four down blocks, four up blocks, one output block, and one Softmax module. In each block, the channel of the output feature map and the number of bottlenecks is shown in the brackets, respectively. The down block comprises one convolution module and some bottlenecks, and the up block includes one de-convolution module and some bottlenecks. The kernel and stride size of the convolution and de-convolution modules are set as k and s, respectively. The bottleneck structure is illustrated in the dotted rectangular box.

FIGURE 2
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Figure 2. The VB-Net network structure.

The algorithm flow chart is shown in Figure 3. At a low image resolution, the general positions of the malleus, incus, and stapes could initially be located. Then, the edges of the three auditory ossicles were finely segmented at a relatively high image resolution.

FIGURE 3
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Figure 3. Algorithm flow chart.

Model training

The two segmentation tasks concerning the auditory ossicles and the image background were trained at a low resolution. First, the outline markers of the malleus, incus, and stapes were combined, and a three-dimensional (3D) morphological expansion algorithm was adopted with a 1 cm expansion in each direction as the ground truth of the coarse locating model. Then, the HRCT image was resampled to [1, 1, 1 mm], a point was randomly selected on the entire image, and an image block of [96, 96, 64] was cut out using this point as the center area. This image block was input into the 3D VB-Net for low-resolution locating model training. The window level of the image normalization was 1,000 HU, and the window width was 3,000 HU. The intensity value, with a CT value between –2,000 and 4,000 HU, was linearly normalized to [–1, 1]. The intensity values greater than 4,000 HU were normalized to 1, and those below –2,000 HU were normalized to –1. A single-class Dice loss function and a cross-entropy loss function were selected as the loss functions, but the weights of both loss functions were equal.

At a high resolution, the malleus, incus, stapes, and the background were segmented. The HRCT image was resampled to [0.2, 0.2, 0.335 mm]. Then, a random point was selected within 20 pixels of the malleus, incus, and stapes masks as the center point to cut out a [96, 96, 96] image block, which was subsequently input into the 3D VB-Net for high-resolution fine segmentation model training. The normalization method was the same as that of the coarse-resolution model training noted above. The loss functions were a multi-class Dice and a cross-entropy loss function, respectively, but the weights of both loss functions were equal. When calculating the loss function, the weights of each class were equal.

Model reasoning

Unlike the image block input in the training stage, the test stage was subject to the network reasoning of the entire image. A multi-resolution strategy was used to connect the low- and high-resolution networks. The goal of the low-resolution network was to roughly locate the position of the organ (the segmentation target: the malleus, incus, and stapes). The entire image was resampled to an isotropic spacing of 1 mm, and the network only focused on the overall region of interest of the auditory ossicles at a lower image resolution. At a high resolution, only the region of interest (extended by 2 cm), obtained from the low-resolution network, was resampled and input into the trained high-resolution network to create the accurate segmentation of each organ boundary under a fine image resolution. A combination of coarse and fine resolutions was adopted for the post-processing of the model.

Segmentation accuracy test

This study verified the stability and effectiveness of the presented model using five-fold cross-validation. That is, 158 sample data sets were randomly divided into a training set, a validation set, and a test set according to an 8:1:1 ratio, and the average accuracy of the model was obtained by averaging the five-fold network’s accuracy. The manual segmentation results of the ENT radiologist served as the ground truth (Powell et al., 2017), and the 3D V-Net and a 3D U-Net model were employed. The following evaluation indicators were used to measure the performance of the segmentation method in this study (Taha and Hanbury, 2015). The dice similarity coefficient (DSC), with a value range from 0 to 1, was used to reflect the similarity coefficient between the automatic and manual segmentation. A value closer to 1 indicated a better model. When the DSC was more than or equal to 0.7, the automatic and manual segmentations were considered to indicate good consistency (Zhong et al., 2021). The DSC is defined as,

D S C = 2 * ( R p * R t ) R p + R t * 100 %

where Rt and Rp are denoted as the gold mask and the predicted mask, respectively.

The average surface distance (ASD) referred to the average deviation of the surface distance of all points on the average surface. The ASD is defined as,

A S D ( X , Y ) = x X m i n y Y d ( x , y ) / | X |

where X and Y are the set of points on the boundary of Rt and Rp, respectively. d(x, y) is denoted as the Euclidean distances between two points.

The maximum Hausdorff distance is defined as,

H D ( X , Y ) = max x X { min y Y { d ( x , y ) } }

where X and Y are the set of points on the boundary of Rt and Rp, respectively. d(x, y) is denoted as the Euclidean distances between two points.

The HD95 is the 95th percentile of Hausdorff distance set.

Statistical method

The SPSS Statistics 22.0 (IBM Company, Armonk, NY, United States) software program was used to conduct paired t-tests on the measured values that were obtained by different methods; P < 0.05 indicated a statistically significant difference.

Implementation details

The Adam optimizer (initial learning rate = 0.01) algorithm was chosen to minimize the loss of neural network. The specific loss of dice is adopted in our method. The dice loss function is defined as,

L D i c e = 1 - 2 * ( R p * R t ) R p + R t * 100 %

where Rt and Rp are denoted as the gold mask and the predicted mask, respectively.

The optimal training epoch of each model was selected, based on the minimum loss of validation data, and the training process was considered to have converged if the loss stopped decreasing for 20 epochs. The framework was implemented in PyTorch 1.7.0 with one Nvidia Tesla V100 graphics processing unit.

Results

For the CT scan of the temporal bone, the ITK-SNAP 3.2 software was used to manually segment all the auditory ossicles, and the manual annotation of the malleus, incus, and stapes were used for the automatic segmentation training of the 3D V-Net and U-Net network structures. The network parameters were obtained through data learning, and the comparison between segmentation of model and expert is shown in Figure 4.

FIGURE 4
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Figure 4. (A–C) The manual segmentation of the auditory ossicles; (D–F) the automatic segmentation of the auditory ossicles using the V-Net method.

As listed in Table 1, patch size and spacing were effective parameters for the model’s performance. To select suitable experimental configurations, the model’s performance, using different training configurations, was compared in accordance with the DSC, the ASD, and the HD 95 (see Table 2). Table 2 indicates that in the coarse model training configuration, the best patch size and spacing were [96, 96, 64] and [1, 1, 1] mm, respectively. The best patch-size and spacing values in the fine model training configuration were [96, 96, 96] and [0.2, 0.2, 0.335] mm, respectively. According to the comparison experiments, the following performance was achieved by the 3D V-Net and 3D U-Net networks using the above-noted configurations.

TABLE 1
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Table 1. The detailed configuration for coarse-to-fine segmentation network.

TABLE 2
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Table 2. Comparison of segmentation performance between different experiment settings (patch size, patch spacing) under 3D V-Net.

On completion of the V-Net network structure training, the auditory ossicles and the manual segmentation images were compared for accuracy using the test set and evaluated in accordance with the DSC, the ASD, and the HD 95. The specific results are shown in Tables 35. Compared with the U-Net method, the 3D V-Net method delivered a segmentation effect similar to that of manual segmentation, and the difference was statistically significant.

TABLE 3
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Table 3. Comparison of DSC between automatic segmentation and manual segmentation under two neural networks.

TABLE 4
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Table 4. Comparison of ASD between automatic segmentation and manual segmentation under two neural networks.

TABLE 5
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Table 5. Comparison of HD95 between automatic segmentation and manual segmentation under two neural networks.

The 3D display of the segmentation result is shown in Figure 5A. The left area of the figure shows the entire auditory ossicle structure, while the right side shows the malleus, incus, and stapes, respectively. Compared with the ground truth, the result of the method was consistent and showed little difference concerning surface distance. Figure 5B shows a comparison of the results of the U-Net and 3D V-Net methods. The result of the U-Net method shows a significant difference between the (green) ground truth reconstruction and the (red) segment reconstruction result.

FIGURE 5
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Figure 5. (A) A three-dimensional display of the segmentation results. On the left side is the segmentation result of the ground truth and the 3D V-Net method. The right side shows the difference in the surface distance between the two results. The auditory ossicles comprise the malleus, incus, and stapes. In this paper, positive values represent over-segmentation, and negative values represent under-segmentation. The left side of the figure corresponds to the left auditory ossicles, and the right corresponds to the right auditory ossicles. (B) Comparison of the segmentation results. The segmentation results of the two methods are compared with the surface coincidence degree of the ground truth. Green is the ground truth reconstruction, and red is the segmentation result reconstruction.

The image segmentation time evaluation proceeded as follows. The average daily work time required for two senior physicians, two intermediate physicians, two junior physicians, and two resident physicians to manually segment 50 cases of auditory ossicles was counted. The average time required for these eight physicians to manually segment the ossicles was 220.31–387.42 s, and the average time required for the model to automatically segment the ossicles was 1.66 s (0.83 s required to segment the left and right ossicles). These results are shown in Table 6.

TABLE 6
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Table 6. Average time for manual segmentation and model segmentation of auditory ossicles.

Discussion

The clinical practice significance of high resolution computed tomography ossicular chain segmentation

The ossicular chain, comprising the malleus, incus, and stapes, is deeply situated within the ear and covered by the tympanic membrane. It acts as a device for conducting sound in the middle ear, and changes in the morphology, position, and density of each auditory ossicle may cause hearing disorders. An accurate evaluation of the auditory ossicles is important for the diagnosis and pretherapeutic evaluation of patients experiencing hearing loss. However, the ossicular chain is situated deep inside the ear, small and delicate, and making a diagnosis related to it is often challenging.

High-resolution computed tomography is an indispensable examination method because it can be used to accurately and clearly reflect the structure of the auditory ossicles (Hiraumi et al., 2019). However, the auditory ossicles are small and are not all located on the same plane. Therefore, it is difficult to observe the auditory ossicles on a conventional CT axial image. Additionally, radiologists must thoroughly observe hundreds of images and conduct post-processing reconstruction of the auditory ossicles (i.e., MPR, CPR, and VR) to evaluate them, which relies heavily on the clinical experience and proficiency of the radiologist as it concerns post-processing techniques and is a time-intensive process that is accompanied by a probability of misdiagnosis or missed diagnosis.

Although the AI-assisted diagnosis technique has been widely applied, research on the AI-assisted diagnosis of small-scale structures, such as the auditory ossicles, is rare. The present study adopted HRCT-based AI to create fully automatic segmentation of the auditory ossicles, thereby contributing to satisfying the needs of patients with ear diseases. Automatic identification and segmentation of the auditory ossicles can significantly assist radiologists and clinicians in making an accurate diagnosis.

Comparison between the artificial intelligence algorithm and other algorithms, and a summary of its advantages and disadvantages

The technical method of computer segmentation of the auditory ossicle structure in the research literature is mainly based on mapping, neural networks, and deep learning. The Powell algorithm is used to automatically segment the anatomical structure in CT images of the temporal bone based on anatomical atlas. The results indicated that the DSC of the malleus and incus on both sides was greater than 0.80, and the DSC of the left and right stapes was 0.58 and 0.48 (Powell et al., 2017), respectively. Mapping-based automatic segmentation delivers excellent results in the normal anatomical structure, but the registration accuracy limits the method, and any anatomical variation may cause the failure of automatic identification and segmentation (Noble et al., 2009; Powell et al., 2017, 2019).

The neural network and deep learning method make up for the deficiency of the above method. Currently, with respect to the neural network structure, the most common network architecture includes a fully convolutional network (FCN) (Shelhamer et al., 2017), a U-Net (Ronneberger et al., 2015), a 3D U-Net (Iek et al., 2016), and a V-Net (Milletari et al., 2016). The FCN was a pioneer of image segmentation and the deep learning technique and adopted an end-to-end convolutional neural network and deconvolution for upsampling. However, as it is not sensitive to image details and can cause a partial loss of information, its segmentation accuracy is low for small structures. Ronneberger et al. (2015) proposed a U-Net method, based on an FCN, and applied the full convolutional network to the field of medical image segmentation. However, the FCN and U-Net can only be used for the identification and segmentation of two-dimensional images, whereas a 3D U-Net and V-Net can be used for the identification and processing of 3D images. Compared to a 3D U-Net, V-Net training gradually became the primary method of medical image segmentation due to its high velocity and the short time it requires to complete (Milletari et al., 2016). Fauser adopted a U-Net method to segment the temporal bone before surgery; in this instance, the DSC of the auditory ossicles was up to 0.75 (Fauser et al., 2019). Lv et al. (2021) applied the W-Net, 3D U-Net, and V-Net methods to automatically segment the temporal bone to obtain the DSCs of the auditory ossicles, which were 0.85, 0.84, and 0.83, respectively. Li et al. (2020) adopted a 3D Deep Supervised Densely (DSD) algorithm to obtain the DSCs of the malleus and the incus, which were both 0.82; however, the stapes was not segmented. Ke et al. applied a 3D convolutional neural network to successfully realize the automatic segmentation of the labyrinth, the auditory ossicles, and the facial nerve in both conventional and abnormal temporal bone CTs and achieved excellent results (Ke et al., 2020; Ding et al., 2021; Wang et al., 2021). Other scholars applied multi-view fusion and deep learning algorithms to design an accurate segmentation of the malleus and the incus and further improved the segmentation accuracy of the stapes with an active contour-loss constraint method (Zhu et al., 2021).

In clinical practice, most auditory-related diseases only involve one or two auditory ossicles. The three auditory ossicles are typically segmented as a whole in most of the existing literature (Lv et al., 2021), which fails to satisfy the needs of a clinical diagnosis and treatment, and restricts clinical application. The size of the combined three auditory ossicles is small and, as such, the segmentation accuracy will be reduced if they are segmented separately. However, the present study’s method adopted two cascade neural networks (from a low to high resolution) and added a bottleneck structure to approximately locate the combined auditory ossicles using low image resolution, then segmenting the delicate structures with high-resolution imaging. The results of this study indicated that the model image of the auditory ossicles was full, the delicate structure displayed was clearer than in a manual sketch, and the DSC of the malleus and the incus was 0.92. The DSC of the stapes was 0.86, which met clinical standards. Meanwhile, the test result of the five-fold cross-validation test proved the stability and validity of this study’s model.

The algorithm adopted in this research significantly improved the segmentation accuracy of the auditory ossicles, particularly that of the stapes. The stapes is the smallest in volume among the auditory ossicles and the most difficult to segment. The existing research adopted different technical methods to do so, but the most DSCs of the stapes was less than that of the other two auditory ossicles. Ke et al. (2020) applied mapping to segmenting the temporal bone, and the obtained DSC of the stapes was less than 0.60. Zhu et al. (2021) adopted a 10-μm grade ear specialized CT data-based multi-view fusion algorithm and an active contour loss constraint method to improve the DSC of the stapes to 0.76. Nikan et al. (2021) carried out a PWD-3DNet algorithm to obtain the DSC of the stapes, which was 0.82, whereas the DSCs of the malleus and incus were lower than that of our approach.

The current study is the first to approximately locate the auditory ossicles, separate local images from the located part, and segment each section of the auditory ossicles using high-resolution images. The coarse positioning and fine segmenting method improved the segmentation accuracy and delivered a stapes DSC of up to 0.84 at a higher image segmentation speed. In Table 7, relevant recent studies are summarized and compared with the present study. The results show that the model of the current algorithm achieved a good performance.

TABLE 7
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Table 7. Comparison of DSC values with other related studies.

Time is another issue to be considered in clinical application, considering that the manual reconstruction of the auditory ossicles is time-consuming. Over 1 year, the average time to reconstruct the unilateral auditory ossicles was 4 min each time, even for an expert radiologist. However, the automatic segmentation of the auditory ossicle structure, completed by the equipment and algorithms adopted in this research, took an average time of 1.66 s, which cannot be achieved by manual segmentation. Therefore, the clinical application of this model will significantly reduce the image post-processing time for the radiologist, thereby largely improving work efficiency.

Prospects and limitations for application of the research

This research has the following limitations: (1) only automatic segmentation of the auditory ossicles was achieved; other major anatomical structures in the temporal bone, such as the cochlea, semicircular canal, and facial nerve were not segmented, thus limiting the clinical application scope of this model; (2) only normal auditory ossicles were identified and segmented; the dysplastic temporal bone was not researched, thus limiting the application of the model in cases of malformed temporal bones in clinical application. Future research on these topics will be conducted.

The existing computer-aided diagnosis system can facilitate disease diagnosis. This study evaluated the normal anatomical structure of the auditory ossicles and achieved an initial positive effect in the automatic reconstruction of the auditory ossicles. In the future, this deep learning technique can be applied to research the absence of the auditory ossicles, the malformation of the cochlea and semicircular canals, as well as deformity of the aquaeductus Fallopii to improve ear lesion diagnosis and differential diagnosis models to achieve medical diagnosis informatization and automation. Doing so will improve the work efficiency of medical staff and lower the misdiagnosis rates of ENT diseases.

Conclusion

This study used a deep learning method to create an automatic approach to the recognition and segmentation of the auditory ossicles. The results indicated that the 3D V-Net convolutional neural network could accomplish high-precision and high-efficiency outcomes to describe the structure of the ossicular chain. It is anticipated that this will benefit the diagnosis and treatment of selected auditory system diseases, such as ossicle destruction, ossicle absence, and ossicle malformation or dysplasia.

Data availability statement

The datasets collected and analyzed during the current study are included in this published article, and the datasets and materials are available from the corresponding author on reasonable request.

Ethics statement

This study protocol was approved by the Clinical Research Ethics Committee of Xi’an No.3 Hospital. Written informed consent was obtained from all of the participants.

Author contributions

X-RW completed the major data integration and manual delineation of auditory ossicles and made a critical revision of the manuscript. XM was a major contributor to manuscript drafting. L-XJ offered ethical support and participated in the collection of part of the data. Y-JG provided the major data sets and put forward the conception of the research. Y-JX and W-XB completed data statistics and analysis. J-LL offered assistance in the integration of the data. QZ devised all figures in this article and designed the algorithm flow. M-FH and FS contributed interpretation of the data and provided technical support. JW finalized the study design and supervised the quality control of the study. All authors read and approved the final manuscript.

Acknowledgments

Part of the samples used in this study was collected in Xi’an Central Hospital, the institution in which the data-provided author once served. Hereon, we are particularly grateful to all the people who have assisted us in this study.

Conflict of interest

M-FH, QZ, and FS were employed by Shanghai United Imaging Intelligence Co., Ltd.

The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Publisher’s note

All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.

Abbreviations

AI, artificial intelligence; ASD, average surface distance; CPR, curved planar reconstruction; CT, computed tomography; DSC, Dice similarity coefficient; ENT, Ear, Nose, and Throat; FCN, convolutional network; HD, Hausdorff distance; HD 95, Hausdorff distance (HD) 95; HRCT, high resolution computed tomography; MPR, multiplanar reformation; VR, volume rendering.

References

Coudray, N., Ocampo, P. S., and Sakellaropoulos, T. (2018). Classification and mutation prediction from non-small cell lung cancer histopathology images using deep learning. Nat. Med. 24, 1559–1567. doi: 10.1177/01945998211044982

PubMed Abstract | CrossRef Full Text | Google Scholar

Ding, A. S., Lu, A., and Li, Z. (2021). Automated registration-based temporal bone computed tomography segmentation for applications in neurotologic surgery [published online ahead of print, 2021 sep 7]. Otolaryngol. Head. Neck Surg. 2021:1945998211044982. doi: 10.1177/01945998211044982

PubMed Abstract | CrossRef Full Text | Google Scholar

Falk, T., Mai, D., and Bensch, R. (2019). U-Net: deep learning for cell counting, detection, and morphometry [published correction appears in nat methods. 2019 Apr;16(4):351]. Nat. Methods 16, 67–70. doi: 10.1038/s41592-019-0356-4

PubMed Abstract | CrossRef Full Text | Google Scholar

Fauser, J., Stenin, I., and Bauer, M. (2019). Toward an automatic preoperative pipeline for image-guided temporal bone surgery. Int. J. Comput. Assist. Radiol. Surg. 14, 967–976. doi: 10.1007/s11548-019-01937-x

PubMed Abstract | CrossRef Full Text | Google Scholar

He, F., Liu, T., and Tao, D. (2020). Why resnet works? Residuals generalize. IEEE Trans. Neural Netw Learn Syst. 31, 5349–5362. doi: 10.1109/TNNLS.2020.2966319

PubMed Abstract | CrossRef Full Text | Google Scholar

Hiraumi, H., Obara, M., Yoshioka, K., Ehara, S., and Sato, H. (2019). Detectability of minute temporal bone structures with ultra-high resolution CT. Auris Nasus Larynx 46, 830–835. doi: 10.1016/j.anl.2019.03.007

PubMed Abstract | CrossRef Full Text | Google Scholar

Hosny, A., Parmar, C., Quackenbush, J., Schwartz, L. H., and Aerts, H. J. W. L. (2018). Artificial intelligence in radiology. Nat. Rev. Cancer 18, 500–510. doi: 10.1038/s41568-018-0016-5

PubMed Abstract | CrossRef Full Text | Google Scholar

Ibragimov, B., Toesca, D., Chang, D., Yuan, Y., Koong, A., and Xing, L. (2018). Development of deep neural network for individualized hepatobiliary toxicity prediction after liver SBRT. Med. Phys. 45, 4763–4774. doi: 10.1002/mp.13122

PubMed Abstract | CrossRef Full Text | Google Scholar

Iek, Z., Abdulkadir, A., and Lienkamp, S. (2016). 3D u-net: learning dense volumetric segmentation from sparse annotation. Springer Cham 2016, 424–432. doi: 10.1007/978-3-319-46723-8_49

CrossRef Full Text | Google Scholar

Jäger, L., Bonell, H., and Liebl, M. (2005). CT of the normal temporal bone: comparison of multi- and single-detector row CT. Radiology 235, 133–141. doi: 10.1148/radiol.2351020895

PubMed Abstract | CrossRef Full Text | Google Scholar

Juliano, A. F., Ginat, D. T., and Moonis, G. (2013). Imaging review of the temporal bone: part I. anatomy and inflammatory and neoplastic processes. Radiology 269, 17–33. doi: 10.1148/radiol.13120733

PubMed Abstract | CrossRef Full Text | Google Scholar

Juliano, A. F., Ginat, D. T., and Moonis, G. (2015). Imaging review of the temporal bone: part II. traumatic, postoperative, and noninflammatory nonneoplastic conditions. Radiology 276, 655–672. doi: 10.1148/radiol.2015140800

PubMed Abstract | CrossRef Full Text | Google Scholar

Ke, J., Lv, Y., and Du, Y. L. (2020). Automatic segmentation of facial nerve, labyrinthine and ossicles in temporal CT by deep learning. Acta Anat. Sinica 51, 653–658. doi: 10.16098/j.issn.0529-1356.2020.05.003

CrossRef Full Text | Google Scholar

Li, M. M. (2021). Application of deep learning technology in breast cancer diagnosis. China Med. Eng. 29, 1–3.

Google Scholar

Li, X., Gong, Z., Yin, H., Zhang, H., Wang, Z., and Zhuo, L. (2020). A 3D deep supervised densely network for small organs of human temporal bone segmentation in CT images. Neural. Netw. 124, 75–85. doi: 10.1016/j.neunet.2020.01.005

PubMed Abstract | CrossRef Full Text | Google Scholar

Lv, Y., Ke, J., Xu, Y., Shen, Y., Wang, J., and Wang, J. (2021). Automatic segmentation of temporal bone structures from clinical conventional CT using a CNN approach. Int. J. Med. Robot. 17:e2229. doi: 10.1002/rcs.2229

PubMed Abstract | CrossRef Full Text | Google Scholar

Milletari, F., Navab, N., and Ahmadi, S. A. (2016). “Net: fully convolutional neural networks for volumetric medical image segmentation[C],” in Proceedings of the International Conference on 3D Vision, (IEEE), 565–571. doi: 10.1109/3DV.2016.79

CrossRef Full Text | Google Scholar

Nikan, S., Van Osch, K., Bartling, M., Allen, D. G., Rohani, S. A., Connors, B., et al. (2021). PWD-3Dnet: a deep learning-based fully-automated segmentation of multiple structures on temporal bone CT scans. IEEE Trans. Image Proc. 30, 739–753. doi: 10.1109/TIP.2020.3038363

PubMed Abstract | CrossRef Full Text | Google Scholar

Noble, J. H., Dawant, B. M., Warren, F. M., and Labadie, R. F. (2009). Automatic identification and 3D rendering of temporal bone anatomy. Otol. Neurotol. 30, 436–442. doi: 10.1097/MAO.0b013e31819e61ed

PubMed Abstract | CrossRef Full Text | Google Scholar

Noussios, G., Chouridis, P., Kostretzis, L., and Natsis, K. (2016). Morphological and morphometrical study of the human ossicular chain: a review of the literature and a meta-analysis of experience over 50 years. J Clin. Med. Res. 8, 76–83.

PubMed Abstract | Google Scholar

Powell, K. A., Kashikar, T., Hittle, B., Stredney, D., Kerwin, T., and Wiet, G. J. (2019). Atlas-based segmentation of temporal bone surface structures. Int. J. Comput. Assist. Radiol. Surg. 14, 1267–1273. doi: 10.1007/s11548-019-01978-2

PubMed Abstract | CrossRef Full Text | Google Scholar

Powell, K. A., Liang, T., Hittle, B., Stredney, D., Kerwin, T., and Wiet, G. J. (2017). Atlas-based segmentation of temporal bone anatomy. Int. J. Comput. Assist. Radiol. Surg 12, 1937–1944. doi: 10.1007/s11548-017-1658-6

PubMed Abstract | CrossRef Full Text | Google Scholar

Ren, S., He, K., Girshick, R., and Sun, J. (2017). Faster R-CNN: towards real-time object detection with region proposal networks. IEEE Trans. Pattern. Anal. Mach. Intell. 39, 1137–1149. doi: 10.1109/TPAMI.2016.2577031

PubMed Abstract | CrossRef Full Text | Google Scholar

Ronneberger, O., Fischer, P., and Brox, T. (2015). U-net: convolutional networks for biomedical image segmentation[C]. Med. Image Comput. Assist. Int. 9351, 234–241. doi: 10.1007/978-3-319-24574-4_28

CrossRef Full Text | Google Scholar

Schmidt-Erfurth, U., Sadeghipour, A., Gerendas, B. S., Waldstein, S. M., and Bogunović, H. (2018). Artificial intelligence in retina. Prog. Retin Eye Res. 67, 1–29. doi: 10.1016/j.preteyeres.2018.07.004

PubMed Abstract | CrossRef Full Text | Google Scholar

Shelhamer, E., Long, J., and Darrell, T. (2017). Fully convolutional networks for semantic segmentation. IEEE Trans. Pattern Anal. Mach. Intell. 39, 640–651. doi: 10.1109/TPAMI.2016.2572683

PubMed Abstract | CrossRef Full Text | Google Scholar

Taha, A. A., and Hanbury, A. (2015). Metrics for evaluating 3D medical image segmentation: analysis, selection, and tool. BMC Med. Imaging 15:29. doi: 10.1186/s12880-015-0068-x

PubMed Abstract | CrossRef Full Text | Google Scholar

Tatlipinar, A., Tuncel, A., Öğredik, E. A., Gökçeer, T., and Uslu, C. (2012). The role of computed tomography scanning in chronic otitis media. Eur. Arch. Otorhinolaryngol. 269, 33–38. doi: 10.1007/s00405-011-1577-z

PubMed Abstract | CrossRef Full Text | Google Scholar

Ting, D. S. W., Cheung, C. Y., and Nguyen, Q. (2019). Deep learning in estimating prevalence and systemic risk factors for diabetic retinopathy: a multi-ethnic study. NPJ Digit Med. 2:24. doi: 10.1038/s41746-019-0097-x

PubMed Abstract | CrossRef Full Text | Google Scholar

Wang, J., Lv, Y., and Wang, J. (2021). Fully automated segmentation in temporal bone CT with neural network: a preliminary assessment study. BMC Med. Imaging 21:166. doi: 10.1186/s12880-021-00698-x

PubMed Abstract | CrossRef Full Text | Google Scholar

Zhou, L. Q., Wang, J. Y., and Yu, S. Y. (2019). Artificial intelligence in medical imaging of the liver. World J. Gastroenterol. 25, 672–682.

Google Scholar

Zhong, Y., Yang, Y., and Fang, Y. (2021). A preliminary experience of implementing deep-learning based auto-segmentation in head and neck cancer: A study on real world clinical cases. Front. Oncol. 11:638197. doi: 10.3389/fonc.2021.638197

PubMed Abstract | CrossRef Full Text | Google Scholar

Zhu, Z. Y., Li, X. G., and Wang, R. X. (2021). Analysis of the performance of a multi-view fusion and active contour constraint based deep learning algorithm for ossicles segmentation on 10 μm otology CT. Natl. Med. J. China 101, 3897–3903. doi: 10.3760/cma.j.cn112137-20210816-01840

PubMed Abstract | CrossRef Full Text | Google Scholar

Keywords: auditory ossicles, automatic segmentation, computed tomography, convolutional neural network, deep learning

Citation: Wang X-R, Ma X, Jin L-X, Gao Y-J, Xue Y-J, Li J-L, Bai W-X, Han M-F, Zhou Q, Shi F and Wang J (2022) Application value of a deep learning method based on a 3D V-Net convolutional neural network in the recognition and segmentation of the auditory ossicles. Front. Neuroinform. 16:937891. doi: 10.3389/fninf.2022.937891

Received: 06 May 2022; Accepted: 06 July 2022;
Published: 31 August 2022.

Edited by:

Ayman Sabry El-Baz, University of Louisville, United States

Reviewed by:

Sarah Ayyad, Mansoura University, Egypt
Basma Elsayed, Mansoura University, Egypt

Copyright © 2022 Wang, Ma, Jin, Gao, Xue, Li, Bai, Han, Zhou, Shi and Wang. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

*Correspondence: Jing Wang, wj_xa@qq.com

These authors have contributed equally to this work

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