SmartEM: machine-learning guided electron microscopy.
Yaron MeirovitchCore Francisco ParkLu MiPavel PotocekShashata SawmyaYicong LiIshaan Singh ChandokThomas L AtheyNeha KarlupiaYuelong WuDaniel R BergerRichard L SchalekHanspeter PfisterRemco SchoenmakersMaurice PeemenJeff William LichtmanAravinthan D T SamuelNir ShavitPublished in: bioRxiv : the preprint server for biology (2024)
Connectomics provides essential nanometer-resolution, synapse-level maps of neural circuits to understand brain activity and behavior. However, few researchers have access to the high-throughput electron microscopes necessary to generate enough data for whole circuit or brain reconstruction. To date, machine-learning methods have been used after the collection of images by electron microscopy (EM) to accelerate and improve neuronal segmentation, synapse reconstruction and other data analysis. With the computational improvements in processing EM images, acquiring EM images has now become the rate-limiting step. Here, in order to speed up EM imaging, we integrate machine-learning into real-time image acquisition in a singlebeam scanning electron microscope. This SmartEM approach allows an electron microscope to perform intelligent, data-aware imaging of specimens. SmartEM allocates the proper imaging time for each region of interest - scanning all pixels equally rapidly, then re-scanning small subareas more slowly where a higher quality signal is required to achieve accurate segmentability, in significantly less time. We demonstrate that this pipeline achieves a 7-fold acceleration of image acquisition time for connectomics using a commercial single-beam SEM. We apply SmartEM to reconstruct a portion of mouse cortex with the same accuracy as traditional microscopy but in less time.
Keyphrases
- electron microscopy
- deep learning
- machine learning
- high resolution
- data analysis
- convolutional neural network
- artificial intelligence
- big data
- high throughput
- optical coherence tomography
- single molecule
- white matter
- cerebral ischemia
- fluorescence imaging
- multiple sclerosis
- resting state
- subarachnoid hemorrhage
- fine needle aspiration