The complex interaction between hematopoietic stem cells (HSCs) and their
microenvironment in the human bone marrow ensures a life-long blood production
by balancing stem cell maintenance and differentiation. This so-called HSC niche
can be disturbed by malignant diseases. Investigating their consequences on
hematopoiesis requires deep understanding of how the niches function in health
and disease. To facilitate this, biomimetic models of the bone marrow are needed
to analyse HSC maintenance and hematopoiesis under steady-state and diseased
conditions. Here, 3D bone marrow models, their fabrication methods (including 3D
bioprinting) and implementations recapturing bone marrow functions in health and
diseases, are presented.
There is an urgent need for 3D cell culture systems that avoid the oversimplifications and artifacts of conventional culture in 2D. However, 3D culture within the cavities of porous biomaterials or large 3D structures harboring high cell numbers is limited by the needs to nurture cells and to remove growth-limiting metabolites. To overcome the diffusion-limited transport of such soluble factors in 3D culture, mixing can be improved by pumping, stirring or shaking, but this in turn can lead to other problems. Using pumps typically requires custom-made accessories that are not compatible with conventional cell culture disposables, thus interfering with cell production processes. Stirring or shaking allows little control over movement of scaffolds in media. To overcome these limitations, magnetic, macroporous hydrogels that can be moved or positioned within media in conventional cell culture tubes in a contactless manner are presented. The cytocompatibility of the developed biomaterial and the applied magnetic fields are verified for human hematopoietic stem and progenitor cells (HSPCs). The potential of this technique for perfusing 3D cultures is demonstrated in a proof-of-principle study that shows that controlled contactless movement of cell-laden magnetic hydrogels in culture media can mimic the natural influence of differently perfused environments on HSPCs.
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