The presence of cancer-associated fibroblast in breast cavity side margins is in correlation with the expression of oncoproteins by adjacent epithelial cells: a new era in cancerous potential.

PURPOSE: Cancer-associated fibroblasts (CAFs) are one of the most critical cells in the tumor environment, with crucial roles in cancer progression and metastasis. Due to Field-Effect phenomena (also called field cancerization), the adjacent cavity side area of the margin is histologically normal, but it has been entered into neoplastic transformation due to MCT4 and MCT1 pathways activated by H2O2/ROS oxidative stress agents secreted by CAF in adjacent tumor bed microenvironment. This paper specifically focused on the role of cancer-associated fibroblast in breast tumor beds and its correlation with the presence of scattered cancer cells or onco-protein-activated cells (may be high risk but not completely transformed cancer cells) in the cavity side margins. METHODS: In this study, the glycolytic behavior of non-tumoral cavity side margins was examined using carbon nanotube-based electrochemical biosensors integrated into a cancer diagnostic probe. This method enabled the detection of CAF accumulation sites in non-cancerous neighboring tissues of tumors, with a correlation to CAF concentration. Subsequently, RT-PCR, fluorescent, histopathological, and invasion assays were conducted on hyperglycolytic lesions to explore any correlation between the abundance of CAFs and the electrochemical responses of the non-cancerous tissues surrounding the tumor, as well as their neoplastic potential. RESULTS: We observed overexpression of cancer-associated transcriptomes as well as the presence and hyperactivation of CAFs in cavity-side regions in which glycolytic metabolism was recorded, independent of the histopathological state of the lesion. At mean 70.4%, 66.7%, 70.4%, and 44.5% increments were observed in GLUT-1, MMP-2, N-cadherin, and MMP-9 transcriptomes by highly glycolytic but histologically cancer-free expression samples in comparison with negative controls (histologically non-cancer lesions with low glycolytic behavior). CONCLUSION: The presence of CAFs is correlated with the presence of high glycolytic metabolism in the cavity margin lesion, high ROS level in the lesion, and finally aggressive cancer-associated proteins (such as MMP2, …) in the margin while these metabolomes, molecules, and proteins are absent in the margins with negatively scored CDP response and low ROS level. So, it seems that when we observe CAFs in glycolytic lesions with high ROS levels, some high-risk epithelial breast cells may exist while no histological trace of cancer cells was observed. Further research on CAFs could provide valuable insights into the local recurrence of malignant breast diseases. Hence, real-time sensors can be used to detect and investigate CAFs in the non-tumoral regions surrounding tumors in cancer patients, potentially aiding in the prevention of cancer recurrence.

Electrochemical therapy (EChT) of cancer tumor with an external anode, a way to achieve pathological complete response.

There is a critical need for re-evaluation of electrochemical therapy (EChT) approaches of solid tumors to address the challenges of the currently used method: incomplete pathological response. The coexistence of anode and cathode in the tumor region resulted in acid-alkaline mixation (buffered pH) when the electrodes are so near each other (d < 1 cm), and in the non-affected lesions when the electrodes are far from each other (d > 1 cm), both have resulted in intact tumoral lesions in EChT field. Here, we presented a designation model study of EChT with an external anode out of the tumor and filled the tumor with dense distribution of cathode electrodes to completely destroy the tumoral lesions without any remaining vital tumoral residues. Anode was located in a biological ionic gel chamber (located on top of the skin) which mediates the ionic interface between the external anode and intratumoral cathode. Our newly reported method can solve the lack of a comprehensive therapeutic guideline for any solid tumors. A remarkable increase in the efficiency of EChT without any over-treating was achieved by alkaline therapy of the tumor (without any limitation in locating cathodic needles all over the tumor) and an external acidic region on top of the skin in a cylindrical gel chamber. We found that the destructive volumes and treating ability of mice tumors by this newly represented method were more significant than the conventional EChT method in fewer therapy sessions and no damage to the skin (both anode and cathode electrodes inside the tumor) (P < 0.05). Results of this study applied to mouse model tumors shed new light on returning attraction to EChT as a valuable complementary method for treating different types of solid breast tumors.