Ultrasound Plane Pose Regression: Assessing Generalized Pose Coordinates in the Fetal Brain.
Chiara Di VeceMaela Le LousBrian P DromeyFrancisco VasconcelosAnna Louise DavidDonald PeeblesDanail StoyanovPublished in: IEEE transactions on medical robotics and bionics (2023)
In obstetric ultrasound (US) scanning, the learner's ability to mentally build a three-dimensional (3D) map of the fetus from a two-dimensional (2D) US image represents a significant challenge in skill acquisition. We aim to build a US plane localization system for 3D visualization, training, and guidance without integrating additional sensors. This work builds on top of our previous work, which predicts the six-dimensional (6D) pose of arbitrarily oriented US planes slicing the fetal brain with respect to a normalized reference frame using a convolutional neural network (CNN) regression network. Here, we analyze in detail the assumptions of the normalized fetal brain reference frame and quantify its accuracy with respect to the acquisition of transventricular (TV) standard plane (SP) for fetal biometry. We investigate the impact of registration quality in the training and testing data and its subsequent effect on trained models. Finally, we introduce data augmentations and larger training sets that improve the results of our previous work, achieving median errors of 2.97 mm and 6.63° for translation and rotation, respectively.
Keyphrases
- convolutional neural network
- resting state
- deep learning
- white matter
- magnetic resonance imaging
- virtual reality
- electronic health record
- functional connectivity
- big data
- pregnant women
- cerebral ischemia
- high resolution
- patient safety
- computed tomography
- ultrasound guided
- electron microscopy
- brain injury
- body composition
- high density
- high intensity
- adverse drug