Rapid detection of neurons in widefield calcium imaging datasets after training with synthetic data.
Yuanlong ZhangGuoxun ZhangXiaofei HanJiamin WuZiwei LiXinyang LiGuihua XiaoHao XieLu FangQionghai DaiPublished in: Nature methods (2023)
Widefield microscopy can provide optical access to multi-millimeter fields of view and thousands of neurons in mammalian brains at video rate. However, tissue scattering and background contamination results in signal deterioration, making the extraction of neuronal activity challenging, laborious and time consuming. Here we present our deep-learning-based widefield neuron finder (DeepWonder), which is trained by simulated functional recordings and effectively works on experimental data to achieve high-fidelity neuronal extraction. Equipped with systematic background contribution priors, DeepWonder conducts neuronal inference with an order-of-magnitude-faster speed and improved accuracy compared with alternative approaches. DeepWonder removes background contaminations and is computationally efficient. Specifically, DeepWonder accomplishes 50-fold signal-to-background ratio enhancement when processing terabytes-scale cortex-wide functional recordings, with over 14,000 neurons extracted in 17 h.
Keyphrases
- high resolution
- spinal cord
- deep learning
- electronic health record
- high speed
- cerebral ischemia
- big data
- risk assessment
- functional connectivity
- single cell
- high throughput
- single molecule
- drinking water
- machine learning
- optical coherence tomography
- climate change
- subarachnoid hemorrhage
- resistance training
- blood brain barrier
- human health
- brain injury
- rna seq
- convolutional neural network
- body composition
- heavy metals
- fluorescence imaging