Label-free intraoperative histology of bone tissue via deep-learning-assisted ultraviolet photoacoustic microscopy.
Rui CaoScott D NelsonSamuel P X DavisYu LiangYilin LuoYide ZhangBrooke CrawfordLihong V WangPublished in: Nature biomedical engineering (2022)
Obtaining frozen sections of bone tissue for intraoperative examination is challenging. To identify the bony edge of resection, orthopaedic oncologists therefore rely on pre-operative X-ray computed tomography or magnetic resonance imaging. However, these techniques do not allow for accurate diagnosis or for intraoperative confirmation of the tumour margins, and in bony sarcomas, they can lead to bone margins up to 10-fold wider (1,000-fold volumetrically) than necessary. Here, we show that real-time three-dimensional contour-scanning of tissue via ultraviolet photoacoustic microscopy in reflection mode can be used to intraoperatively evaluate undecalcified and decalcified thick bone specimens, without the need for tissue sectioning. We validate the technique with gold-standard haematoxylin-and-eosin histology images acquired via a traditional optical microscope, and also show that an unsupervised generative adversarial network can virtually stain the ultraviolet-photoacoustic-microscopy images, allowing pathologists to readily identify cancerous features. Label-free and slide-free histology via ultraviolet photoacoustic microscopy may allow for rapid diagnoses of bone-tissue pathologies and aid the intraoperative determination of tumour margins.
Keyphrases
- label free
- high resolution
- deep learning
- bone mineral density
- magnetic resonance imaging
- computed tomography
- optical coherence tomography
- single molecule
- high speed
- soft tissue
- bone loss
- high throughput
- patients undergoing
- machine learning
- fluorescence imaging
- convolutional neural network
- bone regeneration
- magnetic resonance
- mass spectrometry
- high grade
- contrast enhanced
- liquid chromatography
- tandem mass spectrometry
- loop mediated isothermal amplification