An interdisciplinary team of researchers from the Centre for Nano Science and Engineering (CeNSE) and Department of Molecular Reproduction, Development and Genetics (MRDG) at the Indian Institute of Science (IISc) has made a breakthrough in the field of identifying cancer cells by using a 3D tumor model and magnetically-driven nanomotors to probe the microenvironment of these cells.
“What came as a beautiful surprise was that within such a milieu, we found that aggressive cancer cells ended up remodeling their surroundings by making them stickier, and richer in specifically charged sugars,” assistant professor at MRDG and one of the senior authors Ramray Bhat observed.
“This charging can potentially be used to target and kill tiny populations of cancer cells hidden among their normal counterparts, for which we are extending these studies to living animals,” Bhat added.
In their work, published in Angewandte Chemie, the team has steered helical nanomotors remotely via an external magnetic field through the tumor model to sense, map and quantify changes in the cellular environment.
“We believe these findings will find use as targeting strategies in future in-vivo applications, in quantifications of cancer aggressions and as biophysical probes to study the extracellular environment of cancer,” the team concluded in the journal.
“The model comprises both healthy and cancer cells embedded within a reconstituted basement membrane matrix, and mimics the breast cancer environment,” the paper published Angewandete Chemie stated.
A note released by the IISc claimed that this study also highlights a new way of targeting cancer cells by maneuvering nanomotors inside a tumor and waiting for them to localize in the vicinity of the cancerous site.
“We tried driving the nanomotors toward cancer cells in a tumor model and observed them getting stuck to the matrix near cancer cells, but this was not observed near-normal cells,” the co-first author and PhD student at the CeNSE Debayan Dasgupta said.
“However, when cancer cells secrete fresh material into the ECM, it disrupts the chemical and physical composition of the native ECM surrounding healthy cells, degrading the local environment.
Therefore, understanding how the cellular microenvironment is altered due to cancer cells and measuring these changes quantitatively could be vital in understanding the progression of cancer,” Dasgupta disclosed.
In the current study, the researchers discovered that as the nanomotors approached the cancer cell membrane, they stuck to the matrix more strongly than they would to normal cells. To measure how strongly the nanomotors bound to the matrix, the team calculated the magnetic field strength required to overcome the adhesive force, and move forward.
The reason why the nanomotors appear to stick to the cancer cells better is their charged ECM. This may be due to the presence of 2, 3-linked sialic acid, a sugar-conjugated molecule that confers a negative charge on the cancer cell environment, the researchers found. They visualized the distribution of these sugars using fluorescent markers and found that sialic acids were distributed up to 40 micrometres from the cancer cell surface — the same distance until which the nanomotors experienced strong adhesion.
To counter this adhesive effect, the team coated the nanomotors with perfluorooctyltriethoxysilane (PFO) which shielded them from the charged environment.
Prof. Ghosh further noted that they have demonstrated how the investigation of maneuverability of the nanomotors can be used to spatially differentiate between cancerous and non-cancerous cell niches that were engineered to coexist within tissue-like environment.
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