3D-Printing of succulent plant-like scaffolds with beneficial cell microenvironments for bone regeneration.

Biomimetic materials with complicated structures inspired by natural plants play a critical role in tissue engineering. The succulent plants, with complicated morphologies, show tenacious vitality in extreme conditions due to the physiological functions endowed by their unique anatomical structures. Herein, inspired by the macroscopic structure of succulent plants, succulent plant-like bioceramic scaffolds were fabricated via digital laser processing 3D printing of MgSiO3. Compared with conventional scaffolds with interlaced columns, the structures could prevent cells from leaking from the scaffolds and enhance cell adhesion. The scaffold morphology could be well regulated by changing leaf sizes, shapes, and interlacing methods. The succulent plant-like scaffolds show excellent properties for cell loading as well as cell distribution, promoting cellular interplay, and further enhancing the osteogenic differentiation of bone marrow stem cells. The in vivo study further illustrated that the succulent plant-like scaffolds could accelerate bone regeneration by inducing the formation of new bone tissues. The study suggests that the obtained succulent plant-like scaffold featuring the plant macroscopic structure is a promising biomaterial for regulating cell distribution, enhancing cellular interactions, and further improving bone regeneration.

[1]  Chengtie Wu,et al.  3D printing of conch-like scaffolds for guiding cell migration and directional bone growth , 2022, Bioactive materials.

[2]  Y. S. Zhang,et al.  Biomimetic models of the glomerulus , 2022, Nature Reviews Nephrology.

[3]  K. Ohnuma,et al.  Auto/paracrine factors and early Wnt inhibition promote cardiomyocyte differentiation from human induced pluripotent stem cells at initial low cell density , 2021, Scientific Reports.

[4]  Xiang Li,et al.  Development of hierarchical porous bioceramic scaffolds with controlled micro/nano surface topography for accelerating bone regeneration. , 2021, Materials science & engineering. C, Materials for biological applications.

[5]  A. A. Zadpoor,et al.  3D-Printed Submicron Patterns Reveal the Interrelation between Cell Adhesion, Cell Mechanics, and Osteogenesis , 2021, ACS applied materials & interfaces.

[6]  W. Tuan,et al.  Biphasic ceramic bone graft with biphasic degradation rates. , 2021, Materials science & engineering. C, Materials for biological applications.

[7]  Fei Han,et al.  Natural Biomineralization-Inspired Magnesium Silicate Composite Coating Upregulates Osteogenesis, Enabling Strong Anterior Cruciate Ligament Graft-Bone Healing In Vivo. , 2020, ACS biomaterials science & engineering.

[8]  A. Dolatshahi-Pirouz,et al.  Tough magnesium phosphate-based 3D-printed implants induce bone regeneration in an equine defect model , 2020, Biomaterials.

[9]  R. Müller,et al.  Optimization of Mechanical Stiffness and Cell Density of 3D Bioprinted Cell-laden Scaffolds Improves Extracellular Matrix Mineralization and Cellular Organization for Bone Tissue Engineering. , 2020, Acta biomaterialia.

[10]  Changsheng Liu,et al.  Facilitated vascularization and enhanced bone regeneration by manipulation hierarchical pore structure of scaffolds. , 2020, Materials science & engineering. C, Materials for biological applications.

[11]  Xu Han,et al.  The mystery of coconut overturns the crashworthiness design of composite materials , 2020 .

[12]  Haichun Liu,et al.  Exosomes from bone marrow mesenchymal stem cells enhance fracture healing through the promotion of osteogenesis and angiogenesis in a rat model of nonunion , 2020, Stem Cell Research & Therapy.

[13]  Yingjun Wang,et al.  Regulation of an osteon-like concentric microgrooved surface on osteogenesis and osteoclastogenesis. , 2019, Biomaterials.

[14]  C. Martin,et al.  First report of C4/CAM-cycling photosynthetic pathway in a succulent grass, Spinifex littoreus (Brum. f.) Merr., in coastal regions of Taiwan , 2019, Flora.

[15]  Wenjie Zhang,et al.  A Magnesium‐Enriched 3D Culture System that Mimics the Bone Development Microenvironment for Vascularized Bone Regeneration , 2019, Advanced science.

[16]  Wei Zhu,et al.  Biomimetic 3D-printed scaffolds for spinal cord injury repair , 2019, Nature Medicine.

[17]  Yan Hu,et al.  Osteogenesis of 3D printed porous Ti6Al4V implants with different pore sizes. , 2018, Journal of the mechanical behavior of biomedical materials.

[18]  Chengtie Wu,et al.  Assembly Preparation of Multilayered Biomaterials with High Mechanical Strength and Bone-Forming Bioactivity , 2018, Chemistry of Materials.

[19]  Priya Vashisth,et al.  Development of hybrid scaffold with biomimetic 3D architecture for bone regeneration. , 2018, Nanomedicine : nanotechnology, biology, and medicine.

[20]  H. Falhammar,et al.  Magnesium and Human Health: Perspectives and Research Directions , 2018, International journal of endocrinology.

[21]  Huan Zhou,et al.  Magnesium-based bioceramics in orthopedic applications. , 2018, Acta biomaterialia.

[22]  U. Eggli,et al.  Morphology and Anatomy Support a Reclassification of the African Succulent Taxa of Senecio S.L. (Asteraceae: Senecioneae) , 2017, Haseltonia.

[23]  Wenmiao Shu,et al.  3D bioactive composite scaffolds for bone tissue engineering , 2017, Bioactive materials.

[24]  Guanglong Li,et al.  3D Printing of Lotus Root‐Like Biomimetic Materials for Cell Delivery and Tissue Regeneration , 2017, Advanced science.

[25]  H. Griffiths,et al.  Succulent plants , 2017, Current Biology.

[26]  Shengyuan Yang,et al.  Substrate Curvature Restricts Spreading and Induces Differentiation of Human Mesenchymal Stem Cells. , 2017, Biotechnology journal.

[27]  Nianli Zhang,et al.  Silicates in orthopedics and bone tissue engineering materials. , 2017, Journal of biomedical materials research. Part A.

[28]  Jamie Males Secrets of succulence. , 2017, Journal of experimental botany.

[29]  A. Waas,et al.  Abiotic tooth enamel , 2017, Nature.

[30]  Angelo S. Mao,et al.  Effects of substrate stiffness and cell-cell contact on mesenchymal stem cell differentiation. , 2016, Biomaterials.

[31]  Deyuan Zhang,et al.  Continuous directional water transport on the peristome surface of Nepenthes alata , 2016, Nature.

[32]  S. Gordon Phagocytosis: An Immunobiologic Process. , 2016, Immunity.

[33]  Tomiharu Matsushita,et al.  Effect of pore size on bone ingrowth into porous titanium implants fabricated by additive manufacturing: An in vivo experiment. , 2016, Materials science & engineering. C, Materials for biological applications.

[34]  Qian Wang,et al.  Influence of Surface Topographical Cues on the Differentiation of Mesenchymal Stem Cells in Vitro. , 2016, ACS biomaterials science & engineering.

[35]  Peter X Ma,et al.  Controlled drug release for tissue engineering. , 2015, Journal of controlled release : official journal of the Controlled Release Society.

[36]  TibbitsSkylar,et al.  3D-Printed Wood: Programming Hygroscopic Material Transformations , 2015 .

[37]  Ming S. Liu,et al.  Mg²⁺ coordinating dynamics in Mg:ATP fueled motor proteins. , 2014, The Journal of chemical physics.

[38]  S. Castiglioni,et al.  Magnesium and Osteoporosis: Current State of Knowledge and Future Research Directions , 2013, Nutrients.

[39]  H. Griffiths Plant Venation: From Succulence to Succulents , 2013, Current Biology.

[40]  E. Edwards,et al.  Repeated Origin of Three-Dimensional Leaf Venation Releases Constraints on the Evolution of Succulence in Plants , 2013, Current Biology.

[41]  Wen Yang,et al.  Natural Flexible Dermal Armor , 2013, Advanced materials.

[42]  E. Edwards,et al.  Quantifying succulence: a rapid, physiologically meaningful metric of plant water storage. , 2012, Plant, cell & environment.

[43]  Jian Tang,et al.  The effect of culture conditions on the adipogenic and osteogenic inductions of mesenchymal stem cells on micropatterned surfaces. , 2012, Biomaterials.

[44]  R. Kupferman,et al.  Geometry and Mechanics in the Opening of Chiral Seed Pods , 2011, Science.

[45]  J. Maier,et al.  Magnesium deficiency promotes a pro-atherogenic phenotype in cultured human endothelial cells via activation of NFkB. , 2010, Biochimica et biophysica acta.

[46]  Jian Tang,et al.  The regulation of stem cell differentiation by cell-cell contact on micropatterned material surfaces. , 2010, Biomaterials.

[47]  T. Brodribb,et al.  Angiosperm leaf vein evolution was physiologically and environmentally transformative , 2009, Proceedings of the Royal Society B: Biological Sciences.

[48]  L. Mahadevan,et al.  Optimal vein density in artificial and real leaves , 2008, Proceedings of the National Academy of Sciences.

[49]  G. Edwards,et al.  Occurrence and forms of Kranz anatomy in photosynthetic organs and characterization of NAD-ME subtype C4 photosynthesis in Blepharis ciliaris (L.) B. L. Burtt (Acanthaceae). , 2007, Journal of experimental botany.

[50]  T. Brodribb,et al.  Leaf Maximum Photosynthetic Rate and Venation Are Linked by Hydraulics1[W][OA] , 2007, Plant Physiology.

[51]  L. Sack,et al.  Leaf structural diversity is related to hydraulic capacity in tropical rain forest trees. , 2006, Ecology.

[52]  H. Rubin Central role for magnesium in coordinate control of metabolism and growth in animal cells. , 1975, Proceedings of the National Academy of Sciences of the United States of America.

[53]  L. Canham,et al.  Silicon: the evolution of its use in biomaterials. , 2015, Acta biomaterialia.