Results 91 to 100 of about 32,903 (335)
Standardized 3D bioprinting of soft tissue models with human primary cells [PDF]
, 2015 Cells grown in 3D are more physiologically relevant than cells cultured in 2D. To use 3D models in substance testing and regenerative medicine, reproducibility and standardization are important.Annaheim, Helene, Bleisch, Matthias, Bono, Epifania, Graf-Hausner, Ursula, Rimann, Markus +4 morecore +1 more sourceA Human Neural Tube Model Using 4D Self‐Folding Smart Scaffolds
Advanced Healthcare Materials, EarlyView.Induced pluripotent stem cells (iPSCs) exhibit features comparable to the inner cell mass of the human embryo. iPSCs are applied to a novel self‐folding 4D‐Neural Tube (4D‐NT) structure that mimics the neurulation process. This 4D‐NT model recapitulates early events of human neural development and represents a platform to explore neurodevelopmental ...Claudia Dell'Amico, Irene Chiesa, Angela Toffano, Alessio Esposito, Piera Mancini, Chiara Magliaro, Angeliki Louvi, Carmelo De Maria, Marco Onorati +8 morewiley +1 more sourceGeometrically Tunable Scaffold‐Free Muscle Bioconstructs for Treating Volumetric Muscle Loss
Advanced Healthcare Materials, EarlyView.Volumetric muscle loss is associated with traumatic muscle resulting in permanent functional impairment. Mold‐based, scaffold‐free, high‐density muscle tissue bioconstructs are developed in customizable geometric shapes and sizes. The transplanted rectangular solid‐shaped muscle bioconstructs improved muscle force recovery and tissue regeneration in ...Bugra Ayan, Gaoxian Chen, Ishita Jain, Sha Chen, Gladys Chiang, Caroline Hu, Renato Reyes, Beu P. Oropeza, Ngan F. Huang +8 morewiley +1 more source3D bioactive composite scaffolds for bone tissue engineering [PDF]
, 2017 Bone is the second most commonly transplanted tissue worldwide, with over four million operations using bone grafts or bone substitute materials annually to treat bone defects.Aebi, Ahmed, Ahn, Aho, Aibe, Akmal, Alan, Albrektsson, Alge, Allen, Amaral, Amini, An, Anitha, Anthony, Aravamudhan, Arcos, Armstrong, Ashman, Babiker, Bacakova, Baino, Baldwin, Baraniak, Barnes, Barrere, Bartosh, Bassi, Bellis, Beutner, Bianco, Bidarra, Boccaccio, Bohner, Bohner, Bonfield, Bonjour, Bose, Bose, Bose, Bose, Boskey, Boskey, Breuls, Brydone, Byambaa, Calabrese, Calabrese, Cao, Cao, Cao, Chan, Chandaroy, Chang, Chang, Chen, Chen, Chen, Chen, Chen, Chen, Cheng, Cheng, Chesnutt, Chimene, Choi, Chou, Cipitria, Cohen, Collins, Colnot, Cooke, Cornelissen, Cornelius, Correia, Costa-Pinto, Costa-Pinto, Cui, Cui, Cui, Dahlan, Dai, Daly, Dehghani, Dessi, Dhivya, Di Biase, Dickson, DiMasi, Dimitriou, Ding, Ding, Ding, Do, Doi, Dong, Douglas, Dubbini, Ehlers, Eqtesadi, Evans, Evans, Fan, Faour, Fathi, Faulkner-Jones, Fedorovich, Fedorovich, Fellah, Feng, Feng, Fennema, Ferry, Fu, Furukawa, Gao, Gao, Garcia-Gareta, Gbureck, Geng, Gentile, Gleeson, Gloria, Goncalves, Gonçalves, Gou, Greenwald, Griffin, Grigolo, Guo, Gurkan, Guvendiren, Gyawali, Habibovic, Habraken, Haider, Han, Handschel, Harley, Harley, Hench, Hench, Hench, Hench, Hersel, Higgins, Hing, Hiraoka, Ho, Hollister, Hollister, Hollister, Hollister, Holmes, Hou, Houzhu, Howk, Hsu, Hu, Hua, Huang, Huang, Huang, Huang, Huang, Huang, Huiskes, Hulbert, Hunter, Hutmacher, Hutmacher, Hutmacher, Hwang, Ilharreborde, Illich, Intranuovo, Ishida, Ishii, Jakus, Jakus, Ji, Jiang, Jiang, Jiao, Jin, Jin, Jing, Johnson, Jones, Jones, Jones, Jose, Jose, Kahle, Kaigler, Kane, Kang, Kao, Kapferer, Karageorgiou, Karp, Kasoju, Kavya, Kedong, Kelly, Keriquel, Khanarian, Khattak, Khor, Kim, Kim, Kim, Kim, Kim, Kim, Kim, Kim, Ko, Koch, Kogan, Kokubo, Kolesky, Kruth, Kuboki, Kumar, Kuo, Kurien, Kurtz, Kweon, Lai, Lauren, Leblanc, Lee, Lee, Lee, Lee, Lee, Lee, Lee, LeGeros, Lei, Leong, Levengood, Li, Li, Li, Li, Li, Li, Li, Li, Liang, Liao, Liliang, Lippens, Liu, Liu, Lloyd, Loh, Lopes, Lopez-Heredia, Lou, Lowry, Luo, Lyons, Lyons, Ma, Maglione, Maitz, Malafaya, Mandal, Manferdini, Manke, Maquet, Marcacci, Marco, Markstedt, Marra, Mastrogiacomo, Matsuno, Matthews, Maurus, McMahon, McNamara, Meagher, Melchels, Meng, Michael, Middleton, Miguez-Pacheco, Miri, Mironov, Mironov, Mohseni, Mondrinos, Mooney, Morgan, Mountziaris, Mouthuy, Muller, Munarin, Murphy, Murphy, Muschler, Nair, Nie, Nie, O'Brien, O'Keefe, Oh, Oliveira, Orciani, Orlovskii, Ossipov, Ozbolat, Pan, Parenteau-Bareil, Park, Park, Park, Pasold, Patel, Pati, Patra, Patti, Paul, Peng, Pierschbacher, Polo-Corrales, Prabhakaran, Priya, Puppi, Radhakrishnan, Rahaman, Rajan Unnithan, Rakovsky, Ramaswamy, Ravi, Ren, Ren, Rezwan, Riccardo, Robey, Rodgers, Roohani-Esfahani, Roosa, Rosa, Rouahi, Salerno, Salgado, Saltarrelli, Samorezov, Sandino, Sarac, Saravanan, Sargeant, Saunders, Schantz, Shafiee, Sheikh, Shen, Shengxiang, Shi, Shie, Shikinami, Shin, Shu, Shuai, Shuai, Simon, Smith, Sofia, Solchaga, Spalazzi, Staiger, Stanton, Stolzing, Sui, Sun, Tabriz, Tallawi, Tampieri, Tan, Tan, Tanataweethum, Tarafder, Thadavirul, Thaller, Tharmalingam, Thein-Han, Thompson, Tian, Tian, Tierney, Ting, Tripathi, Tsimbouri, Tsuruga, Ulery, Vaccaro, Vaithilingam, Ventola, Verheyen, Verheyen, Vermeulen, Vila, Villa, Walthers, Wang, Wang, Wang, Wang, Wang, Wang, Wang, Webber, Wei, Wernike, Westhauser, Whang, Whang, White, Williams, Williams, Williams, Woo, Woodruff, Wu, Wu, Wu, Wu, Wu, Wu, Xavier, Xia, Xia, Xie, Xu, Xue, Yamaguchi, Yan, Yan, Yan, Yang, Yang, Yao, Yaszemski, Yoon, Young, Yu, Yu, Yun, Zein, Zeltinger, Zhang, Zhang, Zhang, Zhang, Zhang, Zhang, Zhang, Zhang, Zhao, Zhou, Zhu +464 morecore +2 more sourcesBioprinting Organs—Science or Fiction?—A Review From Students to Students
Advanced Healthcare Materials, EarlyView.Bioprinting artificial organs has the potential to revolutionize the medical field. This is a comprehensive review of the bioprinting workflow delving into the latest advancements in bioinks, materials and bioprinting techniques, exploring the critical stages of tissue maturation and functionality.Nicoletta Murenu, Camilla Mussoni, Mateo S. Andrade Mier, Paula Buettner, Nathaly Chicaiza‐Cabezas, Yi‐Yu Robin Dai, Jessica Faber, Maren Fiedler, Zan Lamberger, Xuen Jen Ng, Vanessa Moessler, Anna Rederer, Jonas Roeder, Sabrina Stecher, Katinka Theis, Jeanette Weigelt, Silvia Budday, Gregor Lang, Natascha Schaefer +18 morewiley +1 more sourceBig bottlenecks in cardiovascular tissue engineering. [PDF]
, 2018 Although tissue engineering using human-induced pluripotent stem cells is a promising approach for treatment of cardiovascular diseases, some limiting factors include the survival, electrical integration, maturity, scalability, and immune response of ...Abilez, Oscar J, Huang, Ngan F, Morris, Viola B, Nakayama, Karina H, Pardon, Gaspard, Pruitt, Beth L, Sayed, Nazish, Serpooshan, Vahid, Wu, Joseph C, Wu, Sean M, Yoon, Young-Sup, Zhang, Jianyi +11 morecore 3D bioprinting of novel biocompatible scaffolds for endothelial cell repair [PDF]
, 2019 The aim of this study was to develop and evaluate an optimized 3D bioprinting technology in order to fabricate novel scaffolds for the application of endothelial cell repair.Ali Nokhodchi, Amit, Dragun, Gordon Ferns, Khong, Lamia Heikal, Maniruzzaman, Mohammed Maniruzzaman, Pietro Ghezzi, Yan Wu +9 morecore +1 more source
