Automated neuron tracking inside moving and deforming C. elegans using deep learning and targeted augmentation.
Core Francisco ParkMahsa Barzegar-KeshteliKseniia KorchaginaAriane DelrocqVladislav SusoyCorinne L JonesAravinthan D T SamuelSahand Jamal RahiPublished in: Nature methods (2023)
Reading out neuronal activity from three-dimensional (3D) functional imaging requires segmenting and tracking individual neurons. This is challenging in behaving animals if the brain moves and deforms. The traditional approach is to train a convolutional neural network with ground-truth (GT) annotations of images representing different brain postures. For 3D images, this is very labor intensive. We introduce 'targeted augmentation', a method to automatically synthesize artificial annotations from a few manual annotations. Our method ('Targettrack') learns the internal deformations of the brain to synthesize annotations for new postures by deforming GT annotations. This reduces the need for manual annotation and proofreading. A graphical user interface allows the application of the method end-to-end. We demonstrate Targettrack on recordings where neurons are labeled as key points or 3D volumes. Analyzing freely moving animals exposed to odor pulses, we uncover rich patterns in interneuron dynamics, including switching neuronal entrainment on and off.
Keyphrases
- deep learning
- convolutional neural network
- cerebral ischemia
- resting state
- white matter
- artificial intelligence
- machine learning
- functional connectivity
- cancer therapy
- soft tissue
- multiple sclerosis
- working memory
- blood brain barrier
- high throughput
- computed tomography
- brain injury
- optical coherence tomography
- drug delivery
- mass spectrometry
- rna seq
- photodynamic therapy
- single cell
- high speed
- pet ct