- Liang, Jesse;
- Sohrabi, Alireza;
- Epperson, Mary;
- Rad, Laila M;
- Tamura, Kelly;
- Sathialingam, Mayilone;
- Skandakumar, Thamira;
- Lue, Philip;
- Huang, Jeremy;
- Popoli, James;
- Yackly, Aidan;
- Bick, Michael;
- Wang, Ze Zhong;
- Chen, Chia-Chun;
- Varuzhanyan, Grigor;
- Damoiseaux, Robert;
- Seidlits, Stephanie K
Cell-matrix interactions mediate complex physiological processes through biochemical, mechanical, and geometrical cues, influencing pathological changes and therapeutic responses. Accounting for matrix effects earlier in the drug development pipeline is expected to increase the likelihood of clinical success of novel therapeutics. Biomaterial-based strategies recapitulating specific tissue microenvironments in 3D cell culture exist but integrating these with the 2D culture methods primarily used for drug screening has been challenging. Thus, the protocol presented here details the development of methods for 3D culture within miniaturized biomaterial matrices in a multi-well plate format to facilitate integration with existing drug screening pipelines and conventional assays for cell viability. Since the matrix features critical for preserving clinically relevant phenotypes in cultured cells are expected to be highly tissue- and disease-specific, combinatorial screening of matrix parameters will be necessary to identify appropriate conditions for specific applications. The methods described here use a miniaturized culture format to assess cancer cell responses to orthogonal variation of matrix mechanics and ligand presentation. Specifically, this study demonstrates the use of this platform to investigate the effects of matrix parameters on the responses of patient-derived glioblastoma (GBM) cells to chemotherapy.