Abstract
Glioma, with its heterogeneous microenvironments and genetic subtypes, presents substantial challenges for treatment prediction and development. We integrated 3D bioprinting and multi-algorithm machine learning as a novel approach to enhance the assessment and understanding of glioma treatment responses and microenvironment characteristics. The bioprinted patient-derived glioma tissues successfully recapitulated molecular properties and drug responses of native tumors. We then developed GlioML, a machine learning workflow incorporating nine distinct algorithms and a weighted ensemble model that generated robust gene expression-based predictors, each reflecting the diverse action mechanisms of various compounds and drugs. The ensemble model superseded the performance of all individual algorithms across diverse in vitro systems, including sphere cultures, complex 3D bioprinted multicellular models, and 3D patient-derived tissues. By integrating bioprinting, the evaluative scope of the treatment expanded to T cell-related therapy and anti-angiogenesis targeted therapy. We identified promising compounds and drugs for glioma treatment and revealed distinct immunosuppressive or angiogenic myeloid-infiltrated tumor microenvironments. These insights pave the way for enhanced therapeutic development for glioma and potentially for other cancers, highlighting the broad application potential of this integrative and translational approach.
Overview
- The study aimed to develop a novel approach to assess and understand glioma treatment responses and microenvironment characteristics using 3D bioprinting and multi-algorithm machine learning. The study successfully recapitulated molecular properties and drug responses of native tumors using bioprinted patient-derived glioma tissues. The machine learning workflow, GlioML, was developed to generate robust gene expression-based predictors for various compounds and drugs. The ensemble model outperformed individual algorithms across diverse in vitro systems, expanding the evaluative scope of treatment to T cell-related therapy and anti-angiogenesis targeted therapy. The study identified promising compounds and drugs for glioma treatment and revealed distinct immunosuppressive or angiogenic myeloid-infiltrated tumor microenvironments, paving the way for enhanced therapeutic development for glioma and potentially for other cancers. The study highlights the broad application potential of this integrative and translational approach.
Comparative Analysis & Findings
- The study compared the outcomes observed under different experimental conditions or interventions, including sphere cultures, complex 3D bioprinted multicellular models, and 3D patient-derived tissues. The results showed that the ensemble model generated by GlioML outperformed individual algorithms across all these in vitro systems. The study also identified distinct immunosuppressive or angiogenic myeloid-infiltrated tumor microenvironments, which have implications for treatment development and personalized medicine. The findings support the potential of the integrative and translational approach for predicting treatment responses and developing novel therapies for glioma and other cancers.
Implications and Future Directions
- The study's findings have significant implications for the field of research and clinical practice, as they highlight the potential of integrative and translational approaches for predicting treatment responses and developing novel therapies for glioma and other cancers. The study also identified limitations, such as the need for larger sample sizes and validation in vivo. Future research directions could include expanding the scope of the study to include other types of cancers, exploring the role of other microenvironments, and developing personalized treatment plans based on the findings. The study's approach could also be applied to other fields, such as drug discovery and precision medicine.