A rapidly magnetically assembled stem cell microtissue with "hamburger" architecture and enhanced vascularization capacity.

With the development of magnetic manipulation technology based on magnetic nanoparticles (MNPs), scaffold-free microtissues can be constructed utilizing the magnetic attraction of MNP-labeled cells. The rapid in vitro construction and in vivo vascularization of microtissues with complex hierarchical architectures are of great importance to the viability and function of stem cell microtissues. Endothelial cells are indispensable for the formation of blood vessels and can be used in the prevascularization of engineered tissue constructs. Herein, safe and rapid magnetic labeling of cells was achieved by incubation with MNPs for 1 h, and ultrathick scaffold-free microtissues with different sophisticated architectures were rapidly assembled, layer by layer, in 5 min intervals. The in vivo transplantation results showed that in a stem cell microtissue with trisection architecture, the two separated human umbilical vein endothelial cell (HUVEC) layers would spontaneously extend to the stem cell layers and connect with each other to form a spatial network of functional blood vessels, which anastomosed with the host vasculature. The "hamburger" architecture of stem cell microtissues with separated HUVEC layers could promote vascularization and stem cell survival. This study will contribute to the construction and application of structural and functional tissues or organs in the future.

The Translation from In Vitro Bioactive Ion Concentration Screening to In Vivo Application for Preventing Peri-implantitis.

Peri-implantitis is a typical pathological condition characterized by the destructive inflammation in the soft tissue and the progressive loss of supporting bones. As the current effective treatments and preventive measures are inconsistent and unpredictable, the use of biomaterials as carriers of bioactive ion coatings is a promising approach. However, the translation from lab to large-scale production and clinical applications is difficult due to a technology barrier. Determining the effective dosage of each ion to achieve an in vivo application of the in vitro screening is challenging. Here, we selected zinc and strontium ions to provide multiple effects on antibacterial activity and osteogenesis. The optimal coating with effective release concentrations of the two ions was obtained after the two-step screening from in vitro testing. The results showed that this type of in vivo bioactive ion usage leads to an enhanced osseointegration during the immediate implantation in a periodontitis-affected environment and prevents soft tissue inflammation and bone resorption in an inflammatory environment. The new biologically active ion screening method could verify the effectiveness of this clinical translation and its potential for large-scale production and could determine the effective dosage of each ion for a specific application.

In situ gas foaming based on magnesium particle degradation: A novel approach to fabricate injectable macroporous hydrogels.

Injectable hydrogels are attractive biomaterials for cell delivery in tissue engineering. However, the in vivo viability of transplanted cells remains limited. Typically, macroporous structures constructed in hydrogels are utilized to enhance oxygen and nutrients diffusion for cell survival and to promote integration between the material and host tissue. A new gas-foaming method to generate pores was proposed by directly adding Mg particles into cell-laden hydrogel solutions, taking advantage of the H2 gas formed during the degradation of Mg. The optimization design of the size and amount of Mg particles added into the hydrogels was investigated. Improved cell viability and proliferation were demonstrated in the group with Mg particles. Additionally, Mg2+ ions generated during Mg degradation facilitated the osteogenic differentiation of stem cells encapsulated in hydrogels. Extensive vascularized bone regeneration in the femoral defects of rats revealed that the use of Mg particles as the foaming agent is feasible, endowing injectable hydrogels with optimized porosity and enhanced bioactivity, and providing a new strategy for future designs of porous hydrogels in tissue engineering.