Construction of complex three-dimensional vascularized liver tissue model in vitro based on a biphasic cell-laden embedding medium by Weikang Lv, Haoran Yu, Abdellah Aazmi, Tuya Naren, Wanli Cheng, Mengfei Yu, Zhen Wang, Xiaobin Xu, Huayong Yang, Liang Ma

Subjects: “…3D bioprinting…”
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Emergent biotechnology applications in urology: a mini review by Chang Liu, Alejandro Rivera Ruiz, Yingchun Zhang, Philippe Zimmern, Zhengwei Li, Zhengwei Li

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Rheological Characterization and Printability of Sodium Alginate–Gelatin Hydrogel for 3D Cultures and Bioprinting by Mohan Kumar Dey, Ram V. Devireddy

“…The development of biocompatible hydrogels for 3D bioprinting is essential for creating functional tissue models and advancing preclinical drug testing. …”
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Mesenchymal Stem Cells and Tissue Bioengineering Applications in Sheep as Ideal Model by Talita D’Paula Tavares Pereira Muniz, Mariana Correa Rossi, Vânia Maria de Vasconcelos Machado, Ana Liz Garcia Alves

“…The most common technologies in tissue engineering include growth factor therapies; metal implants, such as titanium; 3D bioprinting; nanoimprinting for ceramic/polymer scaffolds; and cell therapies, such as mesenchymal stem cells (MSCs). …”
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Current Status of Bioprinting Using Polymer Hydrogels for the Production of Vascular Grafts by Jana Matějková, Denisa Kaňoková, Roman Matějka

“…The fabrication methods are divided into several sections—self-supporting grafts based on simple 3D bioprinting and bioprinting of bioinks on scaffolds made of decellularized or nanofibrous material.…”
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Narrative Review and Guide: State of the Art and Emerging Opportunities of Bioprinting in Tissue Regeneration and Medical Instrumentation by Jaroslava Halper

“…Three-dimensional printing was introduced in the 1980s, though bioprinting started developing a few years later. Today, 3D bioprinting is making inroads in medical fields, including the production of biomedical supplies intended for internal use, such as biodegradable staples. …”
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Sulfated and Phosphorylated Agarose as Biomaterials for a Biomimetic Paradigm for FGF-2 Release by Aurelien Forget, V. Prasad Shastri

“…These modified agaroses offer a simple approach to mimicking electrostatic interactions experienced by GFs in the extracellular environment and provide a platform to probe the role of these interactions in the modulation of growth factor activity and may find utility as an injectable gel for promoting angiogenesis and as bioinks in 3D bioprinting.…”
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Progress in Regenerative Dentistry Approaches: An Update by Maham shah, Reshma khatoon, Rashid Iqbal, Zaheer Ahmed Soomro, Mohsin Ali Dehraj, Muhammad Amin sahito

“…Consider the alternative to conventional root canal therapy provided by pulp revascularization and other regenerative endodontic procedures. Thanks to 3-D bioprinting and computer-aided design, which have revolutionized oral and maxillofacial tissue engineering, modified guided tissue regeneration procedures are gradually replacing standard surgical and nonsurgical periodontal therapy. …”
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Corrigendum to ‘Microstructure development of AM-fabricated pure Zn with heat-treatment and its mechanical properties, degradation behavior, and biocompatibility’ [J Mater Res Tech... by Jie Cui, Long Chao, Jiapeng Ren, Chenrong Ling, Deqiao Xie, Dongsheng Wang, Hengyu Liang, Huixin Liang, Youwen Yang

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Challenges and Innovations in Alveolar Bone Regeneration: A Narrative Review on Materials, Techniques, Clinical Outcomes, and Future Directions by Diana Marian, Giuseppe Toro, Giovanbattista D’Amico, Maria Consiglia Trotta, Michele D’Amico, Alexandru Petre, Ioana Lile, Anca Hermenean, Anca Fratila

“…It examines traditional techniques like guided bone regeneration and bone grafting, alongside newer methods such as stem cell therapy, gene therapy, and 3D bioprinting. Each approach is considered for its strengths in supporting bone growth and integration, especially in cases where complex bone defects make regeneration difficult. …”
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Photochemical corneal cross-linking: Evaluating the potential of a hand-held biopen by Nadina Usseglio, Julia López de Andrés, Juan Antonio Marchal, Lorenzo Moroni, Daniel Nieto

“…The generation of organized 3D tissue constructs that combines cells and photo-crosslinkable biomaterials has been demonstrated using a variety of 3D bioprinting technologies. These technologies have inspired the application for “in situ” bioprinting, resulting on hand-held tools called “Biopens” that can transfer bioprinting capabilities directly into the hands of the surgeons. …”
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Engineering cardiology with miniature hearts by Xiaojun Xia, Miner Hu, Wenyan Zhou, Yunpeng Jin, Xudong Yao

“…We discuss the methodologies for creating cardiac organoids, including self-organization techniques, biomaterial-based scaffolds, 3D bioprinting, and organ-on-chip platforms, which have significantly enhanced the structural complexity and physiological relevance of in vitro cardiac models. …”
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S100A13-driven interaction between pancreatic adenocarcinoma cells and cancer-associated fibroblasts promotes tumor progression through calcium signaling by Liuyuan Xia, Xin Guo, Dong Lu, Yixin Jiang, Xiaohui Liang, Yiwen Shen, Jiayi Lin, Lijun Zhang, Hongzhuan Chen, Jinmei Jin, Xin Luan, Weidong Zhang

“…Furthermore, the protumoral role of S100A13 in PAAD was further verified using both 3D bioprinting and cell line-based xenograft tumor models. …”
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3D In Vitro Human Organ Mimicry Devices for Drug Discovery, Development, and Assessment by Aida Rodriguez-Garcia, Jacqueline Oliva-Ramirez, Claudia Bautista-Flores, Samira Hosseini

“…Organ-on-chip devices, including in vitro modelling of 3D organoids, 3D microfabrication, and 3D bioprinted platforms, play an essential role in drug discovery, testing, and assessment. …”
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