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Plastic pollution severely threatens the resilience of nature. Here, the authors utilize the spore-forming, polymer-degrading bacteria, Bacillus subtilis, as a living filler to develop biocomposite thermoplastic polyurethane with improved mechanical properties and biodegradation.
Glutamine synthetase (GS) relies on Adenosine triphosphate (ATP) to activate glutamate (Glu) and are vital for maintaining ammonia and Glu homeostasis, but GS function is impaired during ATP-deficient neurotoxic events. Here the authors report polyphosphate-manganese nanosheets having GS-like activity independent of ATP to promote the conversion of Glu to glutamine in excitatory neurotoxic cells.
Bioprinting has revitalized tissue regeneration efforts, yet challenges persist due to cell damage during fabrication and mechanical instability of printed scaffolds. Here, the authors develop a mechanical-assisted post-bioprinting strategy for loading cells into hollow scaffolds that effectively repair challenging bone defects.
Neural circuitry is important for comprehending computational mechanisms and physiology of the brain but controlling neuronal connectivity and response in 3D is challenging. Here, titanium carbide MXene-coated 3D polycaprolactone scaffolds are demonstrated to effectively control neuronal interconnection.
The balance of ‘outside–in’ and ‘inside–out’ signaling is critical in tissue development and regeneration. This Comment highlights emerging strategies to engineer and manipulate this delicate equilibrium and fine-tune cellular responses using complementary tools in biomaterials design and synthetic biology.
During fibrotic diseases, functional tissue parenchyma progressively transforms into stiff, disorganized and non-functional tissue causing organ failure. The underlying multitude of interconnected changes in the cellular microenvironment can be investigated using bioengineered fibrosis models.
Over the last few years, there has been a shift towards the use of three-dimensional multicellular structures that more closely recapitulate native tissues and organs as tools to understand development, physiology and pathology.
A bioprinting approach that utilizes organoid-forming stem cells as a living ink within hydrogels guides tissue-scale self-organization to generate more realistic gastrointestinal and vascular tissue constructs.