Scientists from the University of Girona have successfully isolated breast cancer stem cells using additive manufacturing. This investigation has been considered a very important milestone in the research of triple negative breast cancer, one of the most aggressive cancers with a high relapse rate. Using the 3D printer BCN3D Sigma, the research team has been manufactured three-dimensional scaffolds that recreate those structures found in the tissues and fibers of the body. These 3D scaffolds can separate the stem cells that are responsible for causing relapses, in order to study them later for devising pharmaceuticals capable of eliminating them without affecting other cells and avoiding the occurrence of relapses in patients.

To accommodate an optimal three-dimensional cell culture, the main aim was to develop a scaffold architecture that affords a high breast cancer cell proliferation rate. (Credit: BCN3D)

The research team isolated stem cells from one of the most aggressive breast cancers through the use of the additive manufacturing system. The goal of isolating these cells is to facilitate laboratory investigation to find a drug that exclusively attacks these cells and that does not damage healthy parts of the body, thereby preventing patients from suffering a relapse.

Dr. Teresa Puig, one of the researchers directing the project, explains that these tumor cells still remain in the body after treatment via chemotherapy or radiotherapy and that they are responsible for the reappearance of the disease. According to Puig, the cancer being researched is the triple negative subtype, which occurs in young women and leads to relapses within three or four years in 20–30 percent of patients.

Microscopic characterization of PLA scaffold configurations. Top side was visualized under an optical microscope and images were used to calculate pore area and filament diameter. (Credit: BCN3D)

“A tumor is made up of many types of cells, and these are the cells we have in low proportions. Therefore, it is complicated to locate these cells within the tumor. This new system is cleaner, allowing us to work more directly with these types of cells later,” says Puig, director of the oncology unit of the group for the investigation of new therapeutic targets.

To accommodate an optimal 3D cell culture, the main aim was to develop a scaffold architecture that affords a high breast cancer cell proliferation rate. For this purpose, several values of the selected parameters (layer height, infill density, infill pattern, infill direction, and flow) were tested on the slicing software BCN3D Cura to find the optimal ones and 3D printed using the BCN3D Sigma. Using the Taguchi experimental design method, 27 scaffold configurations were manufactured and then analyzed. To perform the characterization and cell proliferation assays, at least 10 copies of each configuration were printed. The objective of the study has been to see which geometric form was most effective in separating the stem cells, the cells responsible for leading to the relapses.

Optical microscope images of cells attached to different scaffolds configurations. White arrows indicate cells adhered to PLA filament. (Credit: BCN3D)

“This structure is a mesh that, on the basis of a series of parameters such as porosities, spaces, and the distance between one element and another, is ultimately able to allow cells to stick to the matrix or not, to grow, and to be able to ‘enrich themselves,’ as our colleagues say,” explains Joaquim de Ciurana, director of the research group on the engineering of products, processes, and production.

Prior to this investigation, these cell cultures were produced two-dimensionally, which did not allow the cells to be effectively separated, and therefore, specific pharmaceuticals could not be produced to attack these cells.

Now, after isolating the stem cells of this sub-type of breast cancer, the researchers will be able to study them in greater depth to find the bio-indicators responsible for the tumors and attack them using pharmaceuticals.

“We still do not know how to treat them, but we have found a way to isolate them,” says Puig. This biomedical engineering project created using 3D printing, known as ONCOen3D, has also allowed reducing the costs of the traditional methodology of analysis, and therefore to increase the experiments carried out with cancer cells.

The results of the study have been published in the scientific journals International Journal of Molecular Sciences and Polymers and have been presented at international congresses.1 A detailed report on the investigation can be found in this paper. The research has been funded in part with money from La Marató de TV3.

Reference

  1. Emma Polonio-Alcal, Marc Rabionet, Antonio J. Guerra, Marc Yeste, Joaquim Ciurana and Teresa Puig, “Screening of Additive Manufactured Scaffolds Designs for Triple Negative Breast Cancer 3D Cell Culture and Stem-Like Expansion,” International Journal of Molecular Sciences.

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