Recent advances in bioengineered scaffold for in vitro meat production

[1]  S. Teoh,et al.  Marine collagen scaffolds in tissue engineering. , 2021, Current opinion in biotechnology.

[2]  Elizabeth A Specht,et al.  Scaffolding Biomaterials for 3D Cultivated Meat: Prospects and Challenges , 2021, Advanced science.

[3]  F. Zenhausern,et al.  The Emerging Role of Decellularized Plant-Based Scaffolds as a New Biomaterial , 2021, International journal of molecular sciences.

[4]  L. P. Tan,et al.  Scaffolds for the manufacture of cultured meat , 2021, Critical reviews in biotechnology.

[5]  D. Bikiaris,et al.  Poly(lactic Acid): A Versatile Biobased Polymer for the Future with Multifunctional Properties—From Monomer Synthesis, Polymerization Techniques and Molecular Weight Increase to PLA Applications , 2021, Polymers.

[6]  R. Choudhary,et al.  A Comparative Review of Natural and Synthetic Biopolymer Composite Scaffolds , 2021, Polymers.

[7]  S. Han,et al.  Current Issues and Technical Advances in Cultured Meat Production: A Review , 2021, Food science of animal resources.

[8]  G. Gaudette,et al.  Decellularized spinach: An edible scaffold for laboratory-grown meat , 2021 .

[9]  K. Ramachandraiah Potential Development of Sustainable 3D-Printed Meat Analogues: A Review , 2021 .

[10]  Mario Moisés Alvarez,et al.  Engineering bioactive synthetic polymers for biomedical applications: a review with emphasis on tissue engineering and controlled release , 2021, Materials Advances.

[11]  E. Sánchez,et al.  Modelling the growth of in-vitro meat on microstructured edible films , 2021 .

[12]  A. Zdunek,et al.  The primary, secondary, and structures of higher levels of pectin polysaccharides. , 2020, Comprehensive reviews in food science and food safety.

[13]  M. Kumar,et al.  Stem cells-derived in vitro meat: from petri dish to dinner plate , 2020, Critical reviews in food science and nutrition.

[14]  D. Choudhury,et al.  3D Printing of cultured meat products , 2020, Critical reviews in food science and nutrition.

[15]  L. Altomare,et al.  Plant Tissues as 3D Natural Scaffolds for Adipose, Bone and Tendon Tissue Regeneration , 2020, Frontiers in Bioengineering and Biotechnology.

[16]  N. Muhammad,et al.  Keratin - Based materials for biomedical applications , 2020, Bioactive materials.

[17]  J. F. Young,et al.  Cultured meat on a plant-based frame , 2020, Nature Food.

[18]  S. Levenberg,et al.  Textured soy protein scaffolds enable the generation of three-dimensional bovine skeletal muscle tissue for cell-based meat , 2020, Nature Food.

[19]  Jian Chen,et al.  Challenges and possibilities for bio-manufacturing cultured meat , 2020 .

[20]  E. Sánchez,et al.  A New Edible Film to Produce In Vitro Meat , 2020, Foods.

[21]  F. Hu,et al.  Red and Processed Meats and Health Risks: How Strong Is the Evidence? , 2020, Diabetes Care.

[22]  H. Mirzadeh,et al.  Alginate Based Scaffolds for Cartilage Tissue Engineering: A Review , 2020, International Journal of Polymeric Materials and Polymeric Biomaterials.

[23]  M. Rave-Fraenk,et al.  Regeneration competent satellite cell niches in rat engineered skeletal muscle , 2019, FASEB bioAdvances.

[24]  C. Driessen,et al.  How Normal Meat Becomes Stranger as Cultured Meat Becomes More Normal; Ambivalence and Ambiguity Below the Surface of Behavior , 2019, Front. Sustain. Food Syst..

[25]  Sik Yoon,et al.  Marine Collagen as A Promising Biomaterial for Biomedical Applications , 2019, Marine drugs.

[26]  Alexandra E. Sexton,et al.  Making Sense of Making Meat: Key Moments in the First 20 Years of Tissue Engineering Muscle to Make Food , 2019, Front. Sustain. Food Syst..

[27]  Marianne J. Ellis,et al.  Bioprocess Design Considerations for Cultured Meat Production With a Focus on the Expansion Bioreactor , 2019, Front. Sustain. Food Syst..

[28]  S. Levenberg,et al.  Tissue Engineering for Clean Meat Production , 2019, Front. Sustain. Food Syst..

[29]  V. Verma,et al.  Stem cell niche: Dynamic neighbor of stem cells. , 2019, European journal of cell biology.

[30]  Andrew E. Pelling,et al.  Scaffolds for 3D Cell Culture and Cellular Agriculture Applications Derived From Non-animal Sources , 2019, Front. Sustain. Food Syst..

[31]  M. E. Gallardo,et al.  iPSCs: A powerful tool for skeletal muscle tissue engineering , 2019, Journal of cellular and molecular medicine.

[32]  M. Rahman Collagen of Extracellular Matrix from Marine Invertebrates and Its Medical Applications , 2019, Marine drugs.

[33]  D. Grant,et al.  Structural, mechanical and swelling characteristics of 3D scaffolds from chitosan-agarose blends. , 2019, Carbohydrate polymers.

[34]  Ralf Smeets,et al.  An Introduction to 3D Bioprinting: Possibilities, Challenges and Future Aspects , 2018, Materials.

[35]  R. Jayakumar,et al.  Carrageenan based hydrogels for drug delivery, tissue engineering and wound healing. , 2018, Carbohydrate polymers.

[36]  Hau D. Le,et al.  Two Methods for Decellularization of Plant Tissues for Tissue Engineering Applications. , 2018, Journal of visualized experiments : JoVE.

[37]  Elizabeth A. Specht,et al.  Opportunities for applying biomedical production and manufacturing methods to the development of the clean meat industry , 2018 .

[38]  Jesse K. Placone,et al.  Recent Advances in Extrusion‐Based 3D Printing for Biomedical Applications , 2018, Advanced healthcare materials.

[39]  Weibiao Zhou,et al.  Extrusion-based food printing for digitalized food design and nutrition control , 2018 .

[40]  Keqing Huang,et al.  Evaluation of tofu as a potential tissue engineering scaffold. , 2018, Journal of materials chemistry. B.

[41]  Ali Khademhosseini,et al.  Three-Dimensional Bioprinting Strategies for Tissue Engineering. , 2018, Cold Spring Harbor perspectives in medicine.

[42]  Ying Yang,et al.  Novel Fabricating Process for Porous Polyglycolic Acid Scaffolds by Melt-Foaming Using Supercritical Carbon Dioxide. , 2017, ACS biomaterials science & engineering.

[43]  Ashish B. Deoghare,et al.  Scaffold Development Using Biomaterials: A Review , 2018 .

[44]  D. Kelly,et al.  Tuning Alginate Bioink Stiffness and Composition for Controlled Growth Factor Delivery and to Spatially Direct MSC Fate within Bioprinted Tissues , 2017, Scientific Reports.

[45]  J. Blaker,et al.  Edible Scaffolds Based on Non-Mammalian Biopolymers for Myoblast Growth , 2017, Materials.

[46]  Elliot S. Bishop,et al.  3-D bioprinting technologies in tissue engineering and regenerative medicine: Current and future trends , 2017, Genes & diseases.

[47]  G. Chaudhry,et al.  Advances and challenges in stem cell culture. , 2017, Colloids and surfaces. B, Biointerfaces.

[48]  Xin Zhao,et al.  Functional and Biomimetic Materials for Engineering of the Three-Dimensional Cell Microenvironment. , 2017, Chemical reviews.

[49]  Jerry Y. H. Fuh,et al.  Design of Three-Dimensional Scaffolds with Tunable Matrix Stiffness for Directing Stem Cell Lineage Specification: An In Silico Study , 2017, Bioengineering.

[50]  Alicia C B Allen,et al.  Electrospun poly(N-isopropyl acrylamide)/poly(caprolactone) fibers for the generation of anisotropic cell sheets. , 2017, Biomaterials science.

[51]  R. Sinha,et al.  Mortality from different causes associated with meat, heme iron, nitrates, and nitrites in the NIH-AARP Diet and Health Study: population based cohort study , 2017, British Medical Journal.

[52]  Jae-Sung Lee,et al.  Biofunctionalized Plants as Diverse Biomaterials for Human Cell Culture , 2017, Advanced healthcare materials.

[53]  A. Lovegrove,et al.  Role of polysaccharides in food, digestion, and health , 2015, Critical reviews in food science and nutrition.

[54]  Ali Khademhosseini,et al.  3D Bioprinting for Tissue and Organ Fabrication , 2016, Annals of Biomedical Engineering.

[55]  Michael R Hamblin,et al.  Chitin and Chitosan: Production and Application of Versatile Biomedical Nanomaterials. , 2016, International journal of advanced research.

[56]  J. Brownlie,et al.  Biotechnological production of hyaluronic acid: a mini review , 2016, 3 Biotech.

[57]  Daniel J. Modulevsky,et al.  Biocompatibility of Subcutaneously Implanted Plant-Derived Cellulose Biomaterials , 2016, bioRxiv.

[58]  K. Anseth,et al.  The design of reversible hydrogels to capture extracellular matrix dynamics , 2016, Nature Reviews Materials.

[59]  Xiujuan Wu,et al.  Genipin-crosslinked, immunogen-reduced decellularized porcine liver scaffold for bioengineered hepatic tissue , 2015, Tissue Engineering and Regenerative Medicine.

[60]  A. Boccaccini,et al.  Strategies for the chemical and biological functionalization of scaffolds for cardiac tissue engineering: a review , 2015, Journal of The Royal Society Interface.

[61]  Elizabeth G Loboa,et al.  Naturally derived and synthetic scaffolds for skeletal muscle reconstruction. , 2015, Advanced drug delivery reviews.

[62]  C. Acevedo,et al.  Improvement of biomaterials used in tissue engineering by an ageing treatment , 2015, Bioprocess and Biosystems Engineering.

[63]  M. Post An alternative animal protein source: cultured beef , 2014, Annals of the New York Academy of Sciences.

[64]  S. C. Shit,et al.  Edible Polymers: Challenges and Opportunities , 2014 .

[65]  L. Gioglio,et al.  Natural and Synthetic Biodegradable Polymers: Different Scaffolds for Cell Expansion and Tissue Formation , 2014 .

[66]  B. Oback,et al.  Dual kinase inhibition promotes pluripotency in finite bovine embryonic cell lines. , 2013, Stem cells and development.

[67]  G. Gerosa,et al.  Cardiomyocytes in vitro adhesion is actively influenced by biomimetic synthetic peptides for cardiac tissue engineering. , 2012, Tissue engineering. Part A.

[68]  J. Werkmeister,et al.  Recombinant protein scaffolds for tissue engineering , 2012, Biomedical materials.

[69]  C. Yao,et al.  Cell adhesion and proliferation enhancement by gelatin nanofiber scaffolds , 2011 .

[70]  R. Lieber,et al.  Structure and function of the skeletal muscle extracellular matrix , 2011, Muscle & nerve.

[71]  R. Marchant,et al.  Design properties of hydrogel tissue-engineering scaffolds , 2011, Expert review of medical devices.

[72]  Eleonora Carletti,et al.  Scaffolds for tissue engineering and 3D cell culture. , 2011, Methods in molecular biology.

[73]  F. Pedreschi,et al.  Using RGB Image Processing for Designing an Alginate Edible Film , 2012, Food and Bioprocess Technology.

[74]  M. V. Van Dyke,et al.  A Review of Keratin-Based Biomaterials for Biomedical Applications , 2010, Materials.

[75]  Fergal J O'Brien,et al.  The effect of mean pore size on cell attachment, proliferation and migration in collagen-glycosaminoglycan scaffolds for bone tissue engineering. , 2010, Biomaterials.

[76]  Gean V. Salmoria,et al.  Structure and mechanical properties of cellulose based scaffolds fabricated by selective laser sintering , 2009 .

[77]  Mark W. Tibbitt,et al.  Hydrogels as extracellular matrix mimics for 3D cell culture. , 2009, Biotechnology and bioengineering.

[78]  Q. Feng,et al.  Preparation of 3-D regenerated fibroin scaffolds with freeze drying method and freeze drying/foaming technique , 2006, Journal of materials science. Materials in medicine.

[79]  D. Mooney,et al.  Hydrogels for tissue engineering: scaffold design variables and applications. , 2003, Biomaterials.

[80]  L G Griffith,et al.  Effect of pore size and void fraction on cellular adhesion, proliferation, and matrix deposition. , 2001, Tissue engineering.