![]() Li X et al “Inkjet Bioprinting of Biomaterials,“ (in eng), Chem Rev, vol. Bioact Mater 7:324–332Īytac Z et al (2022) “Innovations in Craniofacial Bone and Periodontal Tissue Engineering - From Electrospinning to Converged Biofabrication,“ (in eng), International materials reviews, vol. 67, no. 105374,ĭing SJ, Lee S, Ayyagari R, Tang CT, Huynh, Alsberg E (Jan 2022) 4D biofabrication via instantly generated graded hydrogel scaffolds,“ (in eng). 11093–11139, 4 2020.Īrif ZU, Khalid MY, Zolfagharian A, Bodaghi M (2022) “4D bioprinting of smart polymers for biomedical applications: recent progress, challenges, and future perspectives,“ Reactive and Functional Polymers, p. e2109394,įonseca C et al “Emulating Human Tissues and Organs: A Bioprinting Perspective Toward Personalized Medicine,“ Chem Rev, vol. e2201891, Oct 29ĭing et al (2022) “Jammed Micro-Flake Hydrogel for Four-Dimensional Living Cell Bioprinting,“ (in eng), Advanced materials (Deerfield Beach, Fla.), vol. 34, no. Angew Chem Int Ed 59(36):15342–15377ĭíaz-Payno PJ et al (2022) “Swelling-Dependent Shape-Based Transformation of a Human Mesenchymal Stromal Cells-Laden 4D Bioprinted Construct for Cartilage Tissue Engineering,“ (in eng), Adv Healthc Mater, p. Vázquez-González M, Willner I (2020) Stimuli-Responsive Biomolecule-Based hydrogels and their applications. Wang H, Li X, Li M, Wang S, Zuo A, Guo J (2022) “Bioadhesion design of hydrogels: adhesion strategies and evaluation methods for biological interfaces,“ J Adhes Sci Technol, pp. Kirchmajer DM, Gorkin Iii R (2015) An overview of the suitability of hydrogel-forming polymers for extrusion-based 3D-printing. Joshi S, Choudhury SB, Gugulothu SS, Visweswariah, Chatterjee K “Strategies to Promote Vascularization in 3D Printed Tissue Scaffolds: Trends and Challenges,“ Biomacromolecules, vol. 23, no. Xue P et al (2021) Near-infrared light‐driven shape‐morphing of programmable anisotropic hydrogels enabled by MXene nanosheets. Zhou J, Vijayavenkataraman S (2021) “3D-printable conductive materials for tissue engineering and biomedical applications,“ Bioprinting, vol. 24, p. Leu Alexa R et al (2021) “3D-Printed Gelatin Methacryloyl-Based Scaffolds with Potential Application in Tissue Engineering,“ Polymers, vol. 13, no. Sun X, Yao F, Li J (2020) Nanocomposite hydrogel-based strain and pressure sensors: a review. Gladman S, Matsumoto EA, Nuzzo RG, Mahadevan L, Lewis JA (2016) “Biomimetic 4D printing,“ (in eng), Nature materials, vol. 15, no. Comprehensive insights into the constraints, critical requirements for 4D bioprinting including the biocompatibility of materials, precise designs for meticulous transformations, and individual variability in biological interfaces. In addition, we also introduced the applications of 4D hydrogels in tissue repair, vascular grafts, drug delivery, and wearable sensors. In this review, by studying the progress in the field of hydrogels for biointerfaces, we summarized the techniques of 4D printing gels, the classification of bioinks, the design strategies of actuators. Using 3D printing technology, customized functional structures with controllable geometry and trigger ability can be autonomously printed onto desired biological interfaces without considering microfabrication techniques. Stimulation-responsive hydrogels produced by the emerging 4D bioprinting technology are currently considered as encouraging tools for various biomedical applications due to their exciting properties such as stretchability, biocompatibility, ultra-flexibility, and printability. In the definition of 4D printing, the fourth dimension arises from the ability of printed structures to change their shape and/or function over time when exposed to given conditions environmental stimuli, during their post-press life. 4D printed hydrogels are 3D printed objects whose properties and functions are programmable.
0 Comments
Leave a Reply. |
AuthorWrite something about yourself. No need to be fancy, just an overview. ArchivesCategories |