Automatic renal carcinoma biopsy guidance using forward-viewing endoscopic optical coherence tomography and deep learning

Automatic renal carcinoma biopsy guidance using forward-viewing endoscopic optical coherence tomography and deep learning

Percutaneous renal biopsy is commonly used for kidney cancer diagnosis. However, the biopsy procedure remains challenging in sampling accuracy. Here we introduce a forward-viewing optical coherence tomography probe for differentiating tumor and normal tissues, aiming at precise biopsy guidance. Tota...

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Veröffentlicht in:Communications engineering 2024-08, Vol.3 (1), p.107-11, Article 107
Hauptverfasser: Wang, Chen, Cui, Haoyang, Zhang, Qinghao, Calle, Paul, Yan, Yuyang, Yan, Feng, Fung, Kar-Ming, Patel, Sanjay G., Yu, Zhongxin, Duguay, Sean, Vanlandingham, William, Jain, Ajay, Pan, Chongle, Tang, Qinggong
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Sprache:eng
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Artificial neural networks
Attenuation coefficients
Biopsy
Cancer
Classification
Data collection
Deep learning
Diagnosis
Endoscopy
Engineering
Kidney cancer
Kidneys
Lasers
Magnetic resonance imaging
Medical imaging
Optical Coherence Tomography
Tomography
Tumors
Ultrasonic imaging
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Zusammenfassung:Percutaneous renal biopsy is commonly used for kidney cancer diagnosis. However, the biopsy procedure remains challenging in sampling accuracy. Here we introduce a forward-viewing optical coherence tomography probe for differentiating tumor and normal tissues, aiming at precise biopsy guidance. Totally, ten human kidney samples, nine of which had malignant renal carcinoma and one had benign oncocytoma, were used for system evaluation. Based on their distinct imaging features, carcinoma could be efficiently distinguished from normal renal tissues. Additionally, oncocytoma could be differentiated from carcinoma. We developed convolutional neural networks for tissue recognition. Compared to the conventional attenuation coefficient method, convolutional neural network models provided more accurate carcinoma predictions. These models reached a tissue recognition accuracy of 99.1% on a hold-out set of four kidney samples. Furthermore, they could efficiently distinguish oncocytoma from carcinoma. In conclusion, our convolutional neural network-aided endoscopic imaging platform could enhance carcinoma diagnosis during percutaneous renal biopsy procedures. Chen Wang and colleagues develop a forward-viewing optical coherence tomography endoscope for differentiating tumor tissues in renal biopsy. In conjunction with a convolutional neural network developed by the team, tissue recognition rates of over 99% were achieved.
ISSN:2731-3395
2731-3395
DOI:10.1038/s44172-024-00254-9