Related papers: Dense Pixel-Labeling for Reverse-Transfer and Diagnostic Learning on Lung Ultrasound for COVID-19 and Pneumonia Detection

Dense Pixel-Labeling for Reverse-Transfer and Diagnostic Learning on Lung Ultrasound for COVID-19 and Pneumonia Detection

URL: http://arxiv.org/abs/2201.10166v1
Date: Tue, 25 Jan 2022 08:19:11 GMT
Title: Dense Pixel-Labeling for Reverse-Transfer and Diagnostic Learning on Lung Ultrasound for COVID-19 and Pneumonia Detection
Authors: Gautam Rajendrakumar Gare, Andrew Schoenling, Vipin Philip, Hai V Tran, Bennett P deBoisblanc, Ricardo Luis Rodriguez, John Michael Galeotti
Abstract summary: We present an architecture to convert segmentation models to classification models. We compare and contrast dense vs sparse segmentation labeling and study its impact on diagnostic classification.
Score: 0.039025665763971464
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: We propose using a pre-trained segmentation model to perform diagnostic classification in order to achieve better generalization and interpretability, terming the technique reverse-transfer learning. We present an architecture to convert segmentation models to classification models. We compare and contrast dense vs sparse segmentation labeling and study its impact on diagnostic classification. We compare the performance of U-Net trained with dense and sparse labels to segment A-lines, B-lines, and Pleural lines on a custom dataset of lung ultrasound scans from 4 patients. Our experiments show that dense labels help reduce false positive detection. We study the classification capability of the dense and sparse trained U-Net and contrast it with a non-pretrained U-Net, to detect and differentiate COVID-19 and Pneumonia on a large ultrasound dataset of about 40k curvilinear and linear probe images. Our segmentation-based models perform better classification when using pretrained segmentation weights, with the dense-label pretrained U-Net performing the best.

Related papers

Deep Spectral Methods for Unsupervised Ultrasound Image Interpretation [53.37499744840018]
This paper proposes a novel unsupervised deep learning strategy tailored to ultrasound to obtain easily interpretable tissue separations. We integrate key concepts from unsupervised deep spectral methods, which combine spectral graph theory with deep learning methods. We utilize self-supervised transformer features for spectral clustering to generate meaningful segments based on ultrasound-specific metrics and shape and positional priors, ensuring semantic consistency across the dataset.
arXiv Detail & Related papers (2024-08-04T14:30:14Z)
Explanations of Classifiers Enhance Medical Image Segmentation via End-to-end Pre-training [37.11542605885003]
Medical image segmentation aims to identify and locate abnormal structures in medical images, such as chest radiographs, using deep neural networks. Our work collects explanations from well-trained classifiers to generate pseudo labels of segmentation tasks. We then use Integrated Gradients (IG) method to distill and boost the explanations obtained from the classifiers, generating massive diagnosis-oriented localization labels (DoLL) These DoLL-annotated images are used for pre-training the model before fine-tuning it for downstream segmentation tasks, including COVID-19 infectious areas, lungs, heart, and clavicles.
arXiv Detail & Related papers (2024-01-16T16:18:42Z)
Linking data separation, visual separation, and classifier performance using pseudo-labeling by contrastive learning [125.99533416395765]
We argue that the performance of the final classifier depends on the data separation present in the latent space and visual separation present in the projection. We demonstrate our results by the classification of five real-world challenging image datasets of human intestinal parasites with only 1% supervised samples.
arXiv Detail & Related papers (2023-02-06T10:01:38Z)
COVID-19 Detection Using Segmentation, Region Extraction and Classification Pipeline [0.0]
The main purpose of this study is to develop a pipeline for COVID-19 detection from a big and challenging database of CT images. The methodologies tried in the segmentation part are traditional segmentation methods as well as UNet-based methods. In the classification part, a Conal Neural Network (CNN) was used to take the final diagnosis decisions.
arXiv Detail & Related papers (2022-10-06T15:34:29Z)
VAESim: A probabilistic approach for self-supervised prototype discovery [0.23624125155742057]
We propose an architecture for image stratification based on a conditional variational autoencoder. We use a continuous latent space to represent the continuum of disorders and find clusters during training, which can then be used for image/patient stratification. We demonstrate that our method outperforms baselines in terms of kNN accuracy measured on a classification task against a standard VAE.
arXiv Detail & Related papers (2022-09-25T17:55:31Z)
PCA: Semi-supervised Segmentation with Patch Confidence Adversarial Training [52.895952593202054]
We propose a new semi-supervised adversarial method called Patch Confidence Adrial Training (PCA) for medical image segmentation. PCA learns the pixel structure and context information in each patch to get enough gradient feedback, which aids the discriminator in convergent to an optimal state. Our method outperforms the state-of-the-art semi-supervised methods, which demonstrates its effectiveness for medical image segmentation.
arXiv Detail & Related papers (2022-07-24T07:45:47Z)
Improving Classification Model Performance on Chest X-Rays through Lung Segmentation [63.45024974079371]
We propose a deep learning approach to enhance abnormal chest x-ray (CXR) identification performance through segmentations. Our approach is designed in a cascaded manner and incorporates two modules: a deep neural network with criss-cross attention modules (XLSor) for localizing lung region in CXR images and a CXR classification model with a backbone of a self-supervised momentum contrast (MoCo) model pre-trained on large-scale CXR data sets.
arXiv Detail & Related papers (2022-02-22T15:24:06Z)
Cascaded Robust Learning at Imperfect Labels for Chest X-ray Segmentation [61.09321488002978]
We present a novel cascaded robust learning framework for chest X-ray segmentation with imperfect annotation. Our model consists of three independent network, which can effectively learn useful information from the peer networks. Our methods could achieve a significant improvement on the accuracy in segmentation tasks compared to the previous methods.
arXiv Detail & Related papers (2021-04-05T15:50:16Z)
Weakly-Supervised Segmentation for Disease Localization in Chest X-Ray Images [0.0]
We propose a novel approach to the semantic segmentation of medical chest X-ray images with only image-level class labels as supervision. We show that this approach is applicable to chest X-rays for detecting an anomalous volume of air between the lung and the chest wall.
arXiv Detail & Related papers (2020-07-01T20:48:35Z)
A generic ensemble based deep convolutional neural network for semi-supervised medical image segmentation [7.141405427125369]
We propose a generic semi-supervised learning framework for image segmentation based on a deep convolutional neural network (DCNN) Our method is able to significantly improve beyond fully supervised model learning by incorporating unlabeled data.
arXiv Detail & Related papers (2020-04-16T23:41:50Z)
3D medical image segmentation with labeled and unlabeled data using autoencoders at the example of liver segmentation in CT images [58.720142291102135]
This work investigates the potential of autoencoder-extracted features to improve segmentation with a convolutional neural network. A convolutional autoencoder was used to extract features from unlabeled data and a multi-scale, fully convolutional CNN was used to perform the target task of 3D liver segmentation in CT images.
arXiv Detail & Related papers (2020-03-17T20:20:43Z)

This list is automatically generated from the titles and abstracts of the papers in this site.