Fiducial marker detection via deep learning approach for electron tomography

Abstract

Marker-based alignment widely used for tilt series alignment in electron tomography (ET) is crucial to high-resolution tomographic reconstruction. However, accurate alignment with markers remains a challenge because it is difficult to detect markers accurately and obtain the precise positions of fiducial markers in the tilt series. Conventional marker detection algorithms highly depending on marker template and threshold for classification lack the adaptation for different types of samples. The classification accuracy is severely affected by high contrast structures other than markers and high-density areas. In this paper, we present an automatic fiducial marker detection algorithm that applies a fine-tuned classification model to fit with the particular dataset. The classification via a convolutional neural network (CNN) for marker detection is solved as a binary classification problem distinguishing between the positive samples and negative samples. Also, we established the training data for the model to learn the patterns of the fiducial marker and background noise. The experimental results indicate that our deep learning based marker detection algorithm can identify sufficient fiducial markers with high accuracy in a fully automatic manner and shows superiority compared with previous work.