Predicting lymph node metastasis from primary tumor histology and clinicopathologic factors in colorectal cancer using deep learning

Justin D Krogue; Shekoofeh Azizi; Fraser Tan; Isabelle Flament-Auvigne; Trissia Brown; Markus Plass; Robert Reihs; Heimo Müller; Kurt Zatloukal; Pema Richeson; Greg S Corrado; Lily H Peng; Craig H Mermel; Yun Liu; Po-Hsuan Cameron Chen; Saurabh Gombar; Thomas Montine; Jeanne Shen; David F Steiner; Ellery Wulczyn

doi:10.1038/s43856-023-00282-0

Predicting lymph node metastasis from primary tumor histology and clinicopathologic factors in colorectal cancer using deep learning

Commun Med (Lond). 2023 Apr 24;3(1):59. doi: 10.1038/s43856-023-00282-0.

Authors

Justin D Krogue¹, Shekoofeh Azizi², Fraser Tan³, Isabelle Flament-Auvigne⁴, Trissia Brown⁴, Markus Plass⁵, Robert Reihs⁵, Heimo Müller⁵, Kurt Zatloukal⁵, Pema Richeson⁶, Greg S Corrado³, Lily H Peng³, Craig H Mermel³, Yun Liu³, Po-Hsuan Cameron Chen³, Saurabh Gombar⁶, Thomas Montine⁶, Jeanne Shen⁶, David F Steiner³, Ellery Wulczyn³

Affiliations

¹ Google Health, Palo Alto, California, USA. justin.d.krogue@gmail.com.
² Google Research, Brain Team, Toronto, ON, Canada.
³ Google Health, Palo Alto, California, USA.
⁴ Google Health via Vituity, Emeryville, CA, USA.
⁵ Medical University of Graz, Graz, Austria.
⁶ Department of Pathology, Stanford University School of Medicine, Stanford, California, USA.

Abstract

Background: Presence of lymph node metastasis (LNM) influences prognosis and clinical decision-making in colorectal cancer. However, detection of LNM is variable and depends on a number of external factors. Deep learning has shown success in computational pathology, but has struggled to boost performance when combined with known predictors.

Methods: Machine-learned features are created by clustering deep learning embeddings of small patches of tumor in colorectal cancer via k-means, and then selecting the top clusters that add predictive value to a logistic regression model when combined with known baseline clinicopathological variables. We then analyze performance of logistic regression models trained with and without these machine-learned features in combination with the baseline variables.

Results: The machine-learned extracted features provide independent signal for the presence of LNM (AUROC: 0.638, 95% CI: [0.590, 0.683]). Furthermore, the machine-learned features add predictive value to the set of 6 clinicopathologic variables in an external validation set (likelihood ratio test, p < 0.00032; AUROC: 0.740, 95% CI: [0.701, 0.780]). A model incorporating these features can also further risk-stratify patients with and without identified metastasis (p < 0.001 for both stage II and stage III).

Conclusion: This work demonstrates an effective approach to combine deep learning with established clinicopathologic factors in order to identify independently informative features associated with LNM. Further work building on these specific results may have important impact in prognostication and therapeutic decision making for LNM. Additionally, this general computational approach may prove useful in other contexts.

Plain language summary

When colorectal cancers spread to the lymph nodes, it can indicate a poorer prognosis. However, detecting lymph node metastasis (spread) can be difficult and depends on a number of factors such as how samples are taken and processed. Here, we show that machine learning, which involves computer software learning from patterns in data, can predict lymph node metastasis in patients with colorectal cancer from the microscopic appearance of their primary tumor and the clinical characteristics of the patients. We also show that the same approach can predict patient survival. With further work, our approach may help clinicians to inform patients about their prognosis and decide on appropriate treatments.