Vidhi Mathur, Prachi Agarwal, Meghana Kasturi, S Varadharajan, Elsa Sanatombi Devi, Kirthanashri S Vasanthan
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引用次数: 0
Abstract
Transformative bioprinting, particularly 4D printing, is revolutionizing the field of biofabrication, offering dynamic solutions that respond to external stimuli. This paper explores the underlying mechanisms, materials, and stimuli that enable 4D printing to fabricate responsive and adaptive constructs. Section 1 delves into the foundational aspects of 4D bioprinting, detailing the stimuli-responsive materials, such as hydrogels and shape-memory polymers, and the mechanisms that drive their transformation. Additionally, the role of external factors, including temperature, pH, and magnetic or light-based stimuli, is analyzed to provide a comprehensive understanding of this evolving technology. Section 2 focuses on the diverse applications of 4D bioprinting, particularly in biomedical sciences. Key use cases include tissue engineering, drug delivery systems, and the creation of adaptive implants. Beyond healthcare, the potential for smart structures in fields like robotics and aerospace is highlighted, showcasing the technology's ability to deliver tailored, dynamic solutions across various domains. Section 3 categorizes additive manufacturing techniques relevant to 4D printing, offering an in-depth classification and comparison. This includes extrusion-based, vat polymerization, and inkjet printing technologies, emphasizing their compatibility with stimuli-responsive materials. Section 4 shifts focus to commercial advancements, presenting a classification of 4D bioprinters available in the market. The economic barriers, challenges in scalability, and ease of application for these printers are critically examined. Proposed solutions, such as innovative material sourcing, streamlined design strategies, and integration with AI for optimized performance, are presented to address these issues. This work provides a roadmap for integrating 4D bioprinting into scalable and cost-effective production, pushing the boundaries of biofabrication. It serves as a comprehensive guide for researchers and industries aiming to harness the transformative potential of 4D printing for adaptive and functional applications across various domains.
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