Resumen de Development of a 3D in vitro disease model for multiple myeloma
Tissue engineering has evolved towards modeling of human physiology in vitro. The bone marrow (BM) microenvironment is likewise the home of some malignant processes. Multiple myeloma (MM) is a hematological neoplasia characterized by proliferation and BM accumulation of monoclonal plasma cells. Treatments have improved; however, MM remains incurable. Extracellular matrix molecules such as fibronectin (FN) or hyaluronic acid (HA) have a recognized role in drug resistance (DR). The inadequacy of two-dimensional preclinical models is one cause of the DR problem, different in vitro approaches have been developed, however, all these studies are based on hydrogels and scaffolds designed for adherent cells while MM cells are suspension growing cells. The main objective of this Thesis is to develop, optimize and validate a 3D culture platform, termed as microgel, based on microspheres suspended in a liquid media and coexisting with MM cells growing dynamically in suspension.
Different microspheres with different functionalities were developed and characterized. We optimized a suspension polymerization protocol for the obtention of acrylates-based microspheres with two different compositions: with presence (10%) or absence (0%) of acrylic acid (AA). We obtained two different size distributions (< 60 and > 70 ¿m). FN was adsorbed on microsphere surface, while HA, collagen I and different peptide sequences were covalently grafted. Commercial Cytodex 1 microspheres were modified to adapt their characteristics to the microgel platform. Layer-by-layer (LbL) technics were used to introduce HA and chondroitin sulfate (CS) on Cytodex 1 surface. Therefore, a wide repertoire of microspheres has been generated to develop microgels.
The culture conditions for the microgel platform were optimized and validated. Agitation is needed to keep microspheres and cells in suspension. Optimal culture conditions were 150 rpm of stirring speed using orbital shaker and < 60 ¿m diameter microspheres. Microgels with different compositions (0% AA, 10% AA) and functionalizations (none, HA, FN, collagen 1 and peptide sequences) allowed good proliferation of RPMI8226, U226 and MM1.S cells under 3D conditions. All the 3D systems respected the suspension growth pattern which appears as key factor for their good performance in 3D culture. In the initial DR studies, we found that MM cell line RPMI8226 cultured in microgels containing AA showed significantly higher resistance to dexamethasone than their conventional suspension cultures. And that MM cell lines RPMI8226, U226 and MM1.S cultured in microgels containing AA showed significantly higher resistance to bortezomib than their conventional suspension cultures. Thus, AA in the polymeric microsphere matrix showed a positive effect on the generation of DR in vitro and will require further studies. The scale-down of the system to work with smaller volumes of microspheres and reduced cell numbers has been validated, this is of great relevance for their clinical application. Finally, preliminary cultures with the cell line RPMI8226 have been performed with the Cytodex 1-based microgels. Cytodex 1 microspheres without modification had a negative effect on MM cells viability. LbL modification with the pairs chitosan/CS and chitosan/HA increased MM cells viability and proliferation. However, these systems did not respect the non-adherent character of MM cells.
We have developed and validated a novel cell culture system based on a semi-solid 3D media defined by microspheres and MM cells which is specially designed for cells in suspension. It represents a versatile tool that should be further explored for the 3D culture of hematological malignancies and drug resistance studies in vitro.
