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1. Engineered Living Hydrogels

   https://doi.org/10.1002/adma.202201326  

   Liu, Xinyue; Inda, Maria_Eugenia; Lai, Yong; Lu, Timothy_K; Zhao, Xuanhe (April 2022, Advanced Materials)

   Abstract Living biological systems, ranging from single cells to whole organisms, can sense, process information, and actuate in response to changing environmental conditions. Inspired by living biological systems, engineered living cells and nonliving matrices are brought together, which gives rise to the technology of engineered living materials. By designing the functionalities of living cells and the structures of nonliving matrices, engineered living materials can be created to detect variability in the surrounding environment and to adjust their functions accordingly, thereby enabling applications in health monitoring, disease treatment, and environmental remediation. Hydrogels, a class of soft, wet, and biocompatible materials, have been widely used as matrices for engineered living cells, leading to the nascent field of engineered living hydrogels. Here, the interactions between hydrogel matrices and engineered living cells are described, focusing on how hydrogels influence cell behaviors and how cells affect hydrogel properties. The interactions between engineered living hydrogels and their environments, and how these interactions enable versatile applications, are also discussed. Finally, current challenges facing the field of engineered living hydrogels for their applications in clinical and environmental settings are highlighted. 

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2. Growing Living Composites with Ordered Microstructures and Exceptional Mechanical Properties

   https://doi.org/10.1002/adma.202006946  

   Xin, An; Su, Yipin; Feng, Shengwei; Yan, Minliang; Yu, Kunhao; Feng, Zhangzhengrong; Hoon_Lee, Kyung; Sun, Lizhi; Wang, Qiming (February 2021, Advanced Materials)

   Abstract Living creatures are continuous sources of inspiration for designing synthetic materials. However, living creatures are typically different from synthetic materials because the former consist of living cells to support their growth and regeneration. Although natural systems can grow materials with sophisticated microstructures, how to harness living cells to grow materials with predesigned microstructures in engineering systems remains largely elusive. Here, an attempt to exploit living bacteria and 3D‐printed materials to grow bionic mineralized composites with ordered microstructures is reported. The bionic composites exhibit outstanding specific strength and fracture toughness, which are comparable to natural composites, and exceptional energy absorption capability superior to both natural and artificial counterparts. This report opens the door for 3D‐architectured hybrid synthetic–living materials with living ordered microstructures and exceptional properties. 

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3. Robust Self‐Regeneratable Stiff Living Materials Fabricated from Microbial Cells

   https://doi.org/10.1002/adfm.202010784  

   Manjula‐Basavanna, Avinash; Duraj‐Thatte, Anna M.; Joshi, Neel S. (March 2021, Advanced Functional Materials)

   null (Ed.)

   Living systems have not only the exemplary capability to fabricate materials (e.g., wood, bone) under ambient conditions but they also consist of living cells that imbue them with properties like growth and self-regeneration. Like a seed that can grow into a sturdy living wood, can living cells alone serve as the primary building block to fabricate stiff materials? Here is reported the fabrication of stiff living materials (SLMs) produced entirely from microbial cells, without the incorporation of any structural biopolymers (e.g., cellulose, chitin, collagen) or biominerals (e.g., hydroxyapatite, calcium carbonate) that are known to impart stiffness to biological materials. Remarkably, SLMs are also lightweight, strong, and resistant to organic solvents and can self- regenerate. This living materials technology can serve as a powerful biomanu- facturing platform to design and develop advanced structural and cellular materials in a sustainable manner. 

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4. The unexpected influence of legacy conspecific density dependence

   https://doi.org/10.1111/ele.14449  

   Magee, Lukas_J; LaManna, Joseph_A; Wolf, Amy_T; Howe, Robert_W; Lu, Yuanming; Valle, Denis; Smith, Daniel_J_B; Bagchi, Robert; Bauman, David; Johnson, Daniel_J (June 2024, Ecology Letters)

   Abstract When plants die, neighbours escape competition. Living conspecifics could disproportionately benefit because they are freed from negative intraspecific processes; however, if the negative effects of past conspecific neighbours persist, other species might be advantaged, and diversity might be maintained through legacy effects. We examined legacy effects in a mapped forest by modelling the survival of 37,212 trees of 23 species using four neighbourhood properties: living conspecific, living heterospecific, legacy conspecific (dead conspecifics) and legacy heterospecific densities. Legacy conspecific effects proved nearly four times stronger than living conspecific effects; changes in annual survival associated with legacy conspecific density were 1.5% greater than living conspecific effects. Over 90% of species were negatively impacted by legacy conspecific density, compared to 47% by living conspecific density. Our results emphasize that legacies of trees alter community dynamics, revealing that prior research may have underestimated the strength of density dependent interactions by not considering legacy effects. 

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5. Cell‐Laden Hydrogels for Multikingdom 3D Printing

   https://doi.org/10.1002/mabi.202000121  

   Johnston, Trevor G.; Fillman, Jacob P.; Priks, Hans; Butelmann, Tobias; Tamm, Tarmo; Kumar, Rahul; Lahtvee, Petri‐Jaan; Nelson, Alshakim (June 2020, Macromolecular Bioscience)

   Abstract Living materials are created through the embedding of live, whole cells into a matrix that can house and sustain the viability of the encapsulated cells. Through the immobilization of these cells, their bioactivity can be harnessed for applications such as bioreactors for the production of high‐value chemicals. While the interest in living materials is growing, many existing materials lack robust structure and are difficult to pattern. Furthermore, many living materials employ only one type of microorganism, or microbial consortia with little control over the arrangement of the various cell types. In this work, a Pluronic F127‐based hydrogel system is characterized for the encapsulation of algae, yeast, and bacteria to create living materials. This hydrogel system is also demonstrated to be an excellent material for additive manufacturing in the form of direct write 3D‐printing to spatially arrange the cells within a single printed construct. These living materials allow for the development of incredibly complex, immobilized consortia, and the results detailed herein further enhance the understanding of how cells behave within living material matrices. The utilization of these materials allows for interesting applications of multikingdom microbial cultures in immobilized bioreactor or biosensing technologies. 

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