AI Article Synopsis
- The study evaluated a deep learning system (DLS) designed to detect and quantify brain metastases (BMs) to suggest possible treatment options for patients.
- Researchers tested the DLS on 112 newly diagnosed patients, categorizing them into three treatment groups based on the number and volume of detected BMs: limited, moderate, or extensive.
- Results showed a high concordance rate (76.8% accuracy) between DLS suggestions and actual clinical decisions, indicating that the DLS could significantly aid in making timely treatment decisions for patients with BMs.
Article Abstract
Objectives: We aimed to evaluate whether deep learning-based detection and quantification of brain metastasis (BM) may suggest treatment options for patients with BMs.
Methods: The deep learning system (DLS) for detection and quantification of BM was developed in 193 patients and applied to 112 patients that were newly detected on black-blood contrast-enhanced T1-weighted imaging. Patients were assigned to one of 3 treatment suggestion groups according to the European Association of Neuro-Oncology (EANO)-European Society for Medical Oncology (ESMO) recommendations using number and volume of the BMs detected by the DLS: short-term imaging follow-up without treatment (group A), surgery or stereotactic radiosurgery (limited BM, group B), or whole-brain radiotherapy or systemic chemotherapy (extensive BM, group C). The concordance between the DLS-based groups and clinical decisions was analyzed with or without consideration of targeted agents. The performance of distinguishing high-risk (B + C) was calculated.
Results: Among 112 patients (mean age 64.3 years, 63 men), group C had the largest number and volume of BM, followed by group B (4.4 and 851.6 mm) and A (1.5 and 15.5 mm). The DLS-based groups were concordant with the actual clinical decisions, with an accuracy of 76.8% (86 of 112). Modified accuracy considering targeted agents was 81.3% (91 of 112). The DLS showed 95% (82/86) sensitivity and 81% (21/26) specificity for distinguishing the high risk.
Conclusion: DLS-based detection and quantification of BM have the potential to be helpful in the determination of treatment options for both low- and high-risk groups of limited and extensive BMs.
Clinical Relevance Statement: For patients with newly diagnosed brain metastasis, deep learning-based detection and quantification may be used in clinical settings where prompt and accurate treatment decisions are required, which can lead to better patient outcomes.
Key Points: • Deep learning-based brain metastasis detection and quantification showed excellent agreement with ground-truth classifications. • By setting an algorithm to suggest treatment based on the number and volume of brain metastases detected by the deep learning system, the concordance was 81.3%. • When dividing patients into low- and high-risk groups, the sensitivity for detecting the latter was 95%.
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Source |
|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10873231 | PMC |
| http://dx.doi.org/10.1007/s00330-023-10120-5 | DOI Listing |
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