Abstract 290P
Background
The presence of residual disease (RD) after NAT is correlated with a poor outcome in EBC patients. New strategies are required to early identify patients who will not achieve a pathological complete response (pCR). Metabolomics may represent an innovative technology to identify host-related factors correlated with treatment outcome. In this study, we evaluated the predictive ability of metabolomics combined with machine learning in EBC patients receiving NAT.
Methods
Untargeted metabolomic analysis was performed in EBC patients candidates for NAT at our institution. Plasma samples were collected at baseline, before start of treatment. Small molecules were extracted, derivatized and then analysed using bi-dimensional gas chromatography/mass spectrometer (GCxGC-MS). The metabolomic profiling was then evaluated according to response to therapy (pCR versus RD). A machine learning approach was implemented with Boruta features selection algorithm combined with genetical algorithm as classifier, on a training set of 69 samples and validated on the remaining 27.
Results
From 12/2020 to 05/2023, 109 EBC patients have been enrolled (26 ER+, 45 HER2+, 38 TN); surgery was performed in 96 patients so far, with an overall pCR of 51% (ER+ 19%, HER2+ 51%, TN 55%). 61 small molecules were expressed (p<0.05 and Fold Change FC >1.3) between patients in pCR or RD. By multivariate analysis patients with RD showed higher levels of unsaturated fatty acids, as eicosatrienoate (FC=6), 9-decenoic acid (FC=2.2) and 17-octadecynoic acid (FC=2.2) and lower levels of fatty acids, as hexadecenoic acid (FC >100), doconexent (FC=69.5), 9,11-conjugated linoleic acid (FC=5.2), circulating glucose (FC=71) and glucopyranose (FC=23). Pathway analysis revealed the involvement of amino and fatty acid metabolism. A prediction model, combining metabolomics and machine learning, was implemented on 35 metabolomic probes and correctly identified the type of response with an accuracy of 95%.
Conclusions
Our data indicate that host-related metabolomic signatures may identify patients with EBC failing to achieve a pCR after NAT. We identified several fatty acids, amino acids and small molecules that can be modulated through diet. Possible effects by BC subtype are being investigated.
Clinical trial identification
Editorial acknowledgement
Legal entity responsible for the study
A. Gennari.
Funding
AIRC.
Disclosure
A. Gennari: Other, Advisory Board: Roche, AstraZeneca. All other authors have declared no conflicts of interest.
Resources from the same session
325P - Impact of breast tumour location on axillary nodal involvement, chemotherapy use, and survival
Presenter: Yang Xu
Session: Poster session 02
326P - Sentinel lymph node mapping in breast cancer: Evaluating the dual-tracer method with indocyanine green and radioisotope
Presenter: Ava Kwong
Session: Poster session 02
328P - Frequency of radiotherapy-induced malignancies in Li-Fraumeni syndrome patients with early breast cancer and influence of the radiotherapy technique
Presenter: Vanessa Petry
Session: Poster session 02
329P - Pulmonary function and lung fibrosis up to 12 years after breast cancer radiotherapy
Presenter: Jarle Karlsen
Session: Poster session 02
330P - Effect of radiotherapy in deep inspiration in patients with left breast cancer: Does the size of the target area affect the dose for the most crucial organs at risk?
Presenter: Zoltan Locsei
Session: Poster session 02
331P - miR-21 and miR-34a as biomarkers of radiotherapy skin adverse events in ductal carcinoma in situ
Presenter: Tanja Marinko
Session: Poster session 02
332P - Early prediction of residual cancer burden to neoadjuvant chemotherapy in breast cancer by longitudinal MRI-based multitask learning: A multicenter cohort study
Presenter: Wei Li
Session: Poster session 02
333P - Evaluation of a composite PET/CT and HER2 tissue-based biomarker to predict response to neoadjuvant HER2-directed therapy in early breast cancer (TBCRC026)
Presenter: Maeve Hennessy
Session: Poster session 02