3D BIOPRINTING IN DENTISTRY: BIBLIOMETRIC ANALYSIS by Peter Frantsevich Litvitskiy, Alexander Tsymbal, Zhangirkhan Bolat, Yelaman Bazarbayev, Madina Bekentayeva, Raushan Nauryzbay, Azhar N. Zhexenova, Gulbanu Mukyshova, Lida Aliyeva, Aliya Zhylkybekova

Subjects: “…: tooth, 3D bioprinting, three-dimensional bioprinting.…”
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Revolutionizing oral cancer research with 3D bioprinting technology by Bharati R. Doni, Vishnu Priya Veeraraghavan, Madhukar Reddy Rachala, Chaitra Patil, Krishna A. Rao, Santosh R. Patil

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3D Bioprinting: a review of materials, processes and bioink properties by Anna Beatriz Fontes, Raphael Fortes Marcomini

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DNA-encoded dynamic hydrogels for 3D bioprinted cartilage organoids by Ziyu Chen, Hao Zhang, Jingtao Huang, Weizong Weng, Zhen Geng, Mengmeng Li, Jiacan Su

“…Constructing high-fidelity cartilage organoids through three-dimensional (3D) bioprinting to replicate the structure and physiological functions of cartilage is crucial for regenerative medicine, drug screening, and disease modeling. …”
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Innovative bioinks for 3D bioprinting: Exploring technological potential and regulatory challenges by Vidhi Mathur, Prachi Agarwal, Meghana Kasturi, Varadharajan Srinivasan, Raviraja N Seetharam, Kirthanashri S Vasanthan

“…The field of three dimensional (3D) bioprinting has witnessed significant advancements, with bioinks playing a crucial role in enabling the fabrication of complex tissue constructs. …”
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3D bioprinting lobule-like hepatorganoids with induced vascularization for orthotopic implantation by Jianing Yan, Zhichao Ye, Yiwei Lu, Yuyang Yuan, Xiaofeng Wang, Tingting Yan, Jun Yin, Yifan Wang

“…In this research, we developed a 3D bioprinting method using gelatin methacryloyl (GelMA) hydrogel to fabricate lobule-like hepatorganoids, which faithfully mimic the structure of hepatic lobules with lower level of hypoxia (lobule vs 60°, 90°, control; 0.4880 vs 1.009, 0.6778, 0.8704; p < 0.01), high secretion of albumin (lobule vs 60°, 90°, control; 13.47 vs 12.39, 12.65, 10.08 mg/L; p < 0.01) and urea (lobule vs 60°, 90°, control; 5.304 vs 5.233, 4.781, 4.358 mg/L; p < 0.01) in vitro; and promotion of angiogenesis and maintenance of activity following orthotopic implantation. …”
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AI-driven 3D bioprinting for regenerative medicine: From bench to bedside by Zhenrui Zhang, Xianhao Zhou, Yongcong Fang, Zhuo Xiong, Ting Zhang

Subjects: “…3D bioprinting…”
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3D Bioprinting Strategies for Melatonin‐Loaded Polymers in Bone Tissue Engineering by Damla Aykora, Ayhan Oral, Cemre Aydeğer, Metehan Uzun

Subjects: “…3D bioprinting…”
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Advancements in cancer research: 3D bioprinting as an optimal oral tumor model by Aruchamy Mohanprasanth, Muthupandian Saravanan

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3D bioprinting for the production of a perfusable vascularized model of a cancer niche by Federico Maggiotto, Federico Maggiotto, Lorenzo Bova, Lorenzo Bova, Lorenzo Bova, Sara Micheli, Sara Micheli, Camilla Pozzer, Pina Fusco, Pina Fusco, Paolo Sgarbossa, Fabrizio Billi, Elisa Cimetta, Elisa Cimetta

Subjects: “…3D bioprinting…”
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Advanced 3D bioprinted liver models with human-induced hepatocytes for personalized toxicity screening by Yue Ma, Runbang He, Bo Deng, Miaomiao Luo, Wenjie Zhang, Lina Mao, Wenxiang Hu, Yilei Mao, Huayu Yang, Pengyu Huang

“…These hiHeps were then employed in 3D bioprinted liver models with bioink materials that closely mimic the natural extracellular matrix. …”
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A novel platform for oral epithelia sheet biofabrication via magnetic 3D bioprinting by Tien T.T. Truong, Toan V. Phan, Yamin Oo, Oranart Matangkasombut, João N. Ferreira

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Developmental Pathways Pervade Stem Cell Responses to Evolving Extracellular Matrices of 3D Bioprinted Microenvironments by Quyen A. Tran, Visar Ajeti, Brian T. Freeman, Paul J. Campagnola, Brenda M. Ogle

“…To this end, human mesenchymal stem cells (hMSCs) were cultured in 3D bioprinted prisms created from ECM proteins and associated controls. …”
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Manufacture of a chitosan-based bioink with gelatin and hydroxyapatite and its potential application in 3D bioprinting by Sarahí Bautista Reberte, Esmeralda Zuñiga Aguilar, Solange Ivette Rivera Manrique, Carlos Alberto Martínez-Pérez

“…Three-dimensional (3D) bioprinting is a technique currently used for creating tissue engineering scaffolds, using bioinks as the building blocks. …”
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Light‐Processed 3D Bioprinting of Symblepharon Rings Fortified with l‐Ascorbic Acid for Ocular Tissue Engineering by Musa Ayran, Yeliz Goyuk, Aysegul Tiryaki, Songul Ulag, Ayse Ceren Calikoglu Koyuncu, Semra Akkaya Turhan, Oguzhan Gunduz

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Insights on the role of cryoprotectants in enhancing the properties of bioinks required for cryobioprinting of biological constructs by Harshavardhan Budharaju, Dhakshinamoorthy Sundaramurthi, Swaminathan Sethuraman

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Three-Dimensional Bioprinting as a Tool for Tissue Engineering: A Review by Sneha C. Dare, Pavan S. Bajaj, Anand N. Wankhede, Shubham U. Tawade, Khyati N. Manik

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Combining Innovative Bioink and Low Cell Density for the Production of 3D-Bioprinted Cartilage Substitutes: A Pilot Study by Christel Henrionnet, Léa Pourchet, Paul Neybecker, Océane Messaoudi, Pierre Gillet, Damien Loeuille, Didier Mainard, Christophe Marquette, Astrid Pinzano

“…3D bioprinting offers interesting opportunities for 3D tissue printing by providing living cells with appropriate scaffolds with a dedicated structure. …”
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Prospects of emerging 3D bioprinting technologies: major technology components, technology developers, and end users—Part I by Prasanta K. Ghosh

Subjects: “…3d bioprinting…”
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Non-professional phagocytosis of senescent cancer cells revealed in a 3D-bioprinted model of an irradiated lung tumour by Parul Yadav, Pritiranjan Mondal, Sibani Jani, Deepak K. Saini, Kaushik Chatterjee

“…This study explores the application of extrusion-based 3D bioprinting technology to create complex scaffolds mimicking the microenvironment of senescent cancer cells induced by radiotherapy. …”
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