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1. Engineering spatiotemporal organization and dynamics in synthetic cells

   https://doi.org/10.1002/wnan.1685  

   Groaz, Alessandro; Moghimianavval, Hossein; Tavella, Franco; Giessen, Tobias W.; Vecchiarelli, Anthony G.; Yang, Qiong; Liu, Allen P. (November 2020, WIREs Nanomedicine and Nanobiotechnology)

   Abstract Constructing synthetic cells has recently become an appealing area of research. Decades of research in biochemistry and cell biology have amassed detailed part lists of components involved in various cellular processes. Nevertheless, recreating any cellular process in vitro in cell‐sized compartments remains ambitious and challenging. Two broad features or principles are key to the development of synthetic cells—compartmentalization and self‐organization/spatiotemporal dynamics. In this review article, we discuss the current state of the art and research trends in the engineering of synthetic cell membranes, development of internal compartmentalization, reconstitution of self‐organizing dynamics, and integration of activities across scales of space and time. We also identify some research areas that could play a major role in advancing the impact and utility of engineered synthetic cells. This article is categorized under:Biology‐Inspired Nanomaterials > Lipid‐Based StructuresBiology‐Inspired Nanomaterials > Protein and Virus‐Based Structures 

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2. Maladaptive Contractility of 3D Human Cardiac Microtissues to Mechanical Nonuniformity

   https://doi.org/10.1002/adhm.201901373  

   Wang, Chenyan; Koo, Sangmo; Park, Minok; Vangelatos, Zacharias; Hoang, Plansky; Conklin, Bruce_R; Grigoropoulos, Costas_P; Healy, Kevin_E; Ma, Zhen (February 2020, Advanced Healthcare Materials)

   Abstract Cardiac tissues are able to adjust their contractile behavior to adapt to the local mechanical environment. Nonuniformity of the native tissue mechanical properties contributes to the development of heart dysfunctions, yet the current in vitro cardiac tissue models often fail to recapitulate the mechanical nonuniformity. To address this issue, a 3D cardiac microtissue model is developed with engineered mechanical nonuniformity, enabled by 3D‐printed hybrid matrices composed of fibers with different diameters. When escalating the complexity of tissue mechanical environments, cardiac microtissues start to develop maladaptive hypercontractile phenotypes, demonstrated in both contractile motion analysis and force‐power analysis. This novel hybrid system could potentially facilitate the establishment of “pathologically‐inspired” cardiac microtissue models for deeper understanding of heart pathology due to nonuniformity of the tissue mechanical environment. 

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3. Spatially organized cellular communities form the developing human heart

   https://doi.org/10.1038/s41586-024-07171-z  

   Farah, Elie N; Hu, Robert K; Kern, Colin; Zhang, Qingquan; Lu, Ting-Yu; Ma, Qixuan; Tran, Shaina; Zhang, Bo; Carlin, Daniel; Monell, Alexander; et al (March 2024, Nature)

   Abstract The heart, which is the first organ to develop, is highly dependent on its form to function^1,2. However, how diverse cardiac cell types spatially coordinate to create the complex morphological structures that are crucial for heart function remains unclear. Here we integrated single-cell RNA-sequencing with high-resolution multiplexed error-robust fluorescence in situ hybridization to resolve the identity of the cardiac cell types that develop the human heart. This approach also provided a spatial mapping of individual cells that enables illumination of their organization into cellular communities that form distinct cardiac structures. We discovered that many of these cardiac cell types further specified into subpopulations exclusive to specific communities, which support their specialization according to the cellular ecosystem and anatomical region. In particular, ventricular cardiomyocyte subpopulations displayed an unexpected complex laminar organization across the ventricular wall and formed, with other cell subpopulations, several cellular communities. Interrogating cell–cell interactions within these communities using in vivo conditional genetic mouse models and in vitro human pluripotent stem cell systems revealed multicellular signalling pathways that orchestrate the spatial organization of cardiac cell subpopulations during ventricular wall morphogenesis. These detailed findings into the cellular social interactions and specialization of cardiac cell types constructing and remodelling the human heart offer new insights into structural heart diseases and the engineering of complex multicellular tissues for human heart repair. 

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4. Process hybridization schemes for multiscale engineered tissue biofabrication

   https://doi.org/10.1002/wnan.1673  

   Chansoria, Parth; Schuchard, Karl; Shirwaiker, Rohan A. (October 2020, WIREs Nanomedicine and Nanobiotechnology)

   Abstract Recapitulation of multiscale structure–function properties of cells, cell‐secreted extracellular matrix, and 3D architecture of natural tissues is central to engineering biomimetic tissue substitutes. Toward achieving biomimicry, a variety of biofabrication processes have been developed, which can be broadly classified into five categories—fiber and fabric formation, additive manufacturing, surface modification, remote fields, and other notable processes—each with specific advantages and limitations. The majority of biofabrication literature has focused on using a single process at a time, which often limits the range of tissues that could be created with relevant features that span nano to macro scales. With multiscale biomimicry as the goal, development of hybrid biofabrication strategies that synergistically unite two or more processes to complement each other's strengths and limitations has been steadily increasing. This work discusses recent literature in this domain and attempts to equip the reader with the understanding of selecting appropriate processes that can harmonize toward creating engineered tissues with appropriate multiscale structure–function properties. Opportunities related to various hybridization schemes and a future outlook on scale‐up biofabrication have also been discussed. This article is categorized under:Nanotechnology Approaches to Biology > Nanoscale Systems in BiologyImplantable Materials and Surgical Technologies > Nanotechnology in Tissue Repair and Replacement 

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5. Dynamic mechanobiology of cardiac cells and tissues: Current status and future perspective

   https://doi.org/10.1063/5.0141269  

   Wang, Chenyan; Ramahdita, Ghiska; Genin, Guy; Huebsch, Nathaniel; Ma, Zhen (March 2023, Biophysics Reviews)

   Mechanical forces impact cardiac cells and tissues over their entire lifespan, from development to growth and eventually to pathophysiology. However, the mechanobiological pathways that drive cell and tissue responses to mechanical forces are only now beginning to be understood, due in part to the challenges in replicating the evolving dynamic microenvironments of cardiac cells and tissues in a laboratory setting. Although many in vitro cardiac models have been established to provide specific stiffness, topography, or viscoelasticity to cardiac cells and tissues via biomaterial scaffolds or external stimuli, technologies for presenting time-evolving mechanical microenvironments have only recently been developed. In this review, we summarize the range of in vitro platforms that have been used for cardiac mechanobiological studies. We provide a comprehensive review on phenotypic and molecular changes of cardiomyocytes in response to these environments, with a focus on how dynamic mechanical cues are transduced and deciphered. We conclude with our vision of how these findings will help to define the baseline of heart pathology and of how these in vitro systems will potentially serve to improve the development of therapies for heart diseases. 

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