3D-Printed Biomimetic Hierarchical Nacre Architecture: Fracture Behavior and Analysis

Patadiya, Jigar; Wang, Xungai; Joshi, Ganapati; Kandasubramanian, Balasubramanian; Naebe, Minoo

doi:10.1021/acsomega.2c08076

Cited by 11 publications

(2 citation statements)

References 70 publications

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“…), selective laser sintering (SLS)(a technique utilizing powder that melts and fuses powders using laser radiation and then stacks the powders layer by layer), selective laser melting (melting and deposition of powder layers one after another using a high-density laser beam.) and fused deposition modeling (FDM)(a piece of equipment based on extrusion principle) [28][29][30]. Over the last few years, the biomedical industry has substantially used multi-dimensional printers due to their capacity to quickly and economically produce huge, complex models [29].…”

Section: Introductionmentioning

confidence: 99%

Recent advancement and trends in the development of membranes having bactericidal attributes via direct ink writing

Lanke,

Patadiya,

Banerjee

et al. 2024

Biomed. Mater.

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The necessity for orthopedic prostheses, implants, and membranes to treat diseases, trauma, and other disasters has increased as the risk of survive through various factors has intensified exponentially. Considering exponential growth in demand, it has been observed that the traditional technology of grafts and membranes lags to fulfill the demand and effectiveness simultaneously. These challenges in traditional methodologies prompted a revolutionary shift in the biomedical industry when Additive manufacturing (AM) emerged as an alternative fabrication technique for medical equipments such as prostheses, implants, and membranes. However these techniques were fast and precise the major attributes of the biomedical materials were the processability, bactericidal nature, biocompatibility, biodegradability, and nontoxicity together with good mechanical properties. Major challenges faced by researchers in the present-day scenario regarding materials are the lack of bactericidal attributes in tailored material, though having better mechanical as well as biocompatible properties, which, on the other hand, are primary critical factors too, in the healthcare sector. Hence considering the advantages of additive manufacturing and need for membranes with bacteriacidal attributes this present review will highlight the studies based on the manufacturing of membranes with bacteria-resistant properties majorly using direct ink writing and some additive manufacturing techniques and the reasoning behind the antibacterial attributes of those composite materials.

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Section: Introductionmentioning

confidence: 99%

Recent advancement and trends in the development of membranes having bactericidal attributes via direct ink writing

Lanke,

Patadiya,

Banerjee

et al. 2024

Biomed. Mater.

Self Cite

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“…Replicating these complex designs at both the laboratory and industrial scale has been challenging in the past decade. However, it has now become possible to use 3D printers. − These printers provide robust platforms for printing a diverse range of materials and can mimic complex designs found in nature. − They can incorporate various material properties such as mechanical, chemical, optical, electrical, etc. Moreover, 3D printers offer sustainability, flexibility, and customization, resulting in minimal waste and almost ready-to-use products with minimal postprocessing …”

Section: Introductionmentioning

confidence: 99%

Unleashing Enhanced Compressive Strength: 3D Printed Octopus-Inspired Suction Cups Using Topological Engineering

Dixit,

Das,

Singh

et al. 2023

ACS Appl. Polym. Mater.

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Nature's intricate designs and efficient functionality have evolved over millions of years to thrive in challenging environments while minimizing energy consumption and ecological impact. Inspired by nature's strategies, the manufacturing industry and academic research strive to develop materials and designs that exhibit high strength. The octopus, a remarkable marine creature, exemplifies a complex and adaptive design. It has eight arms aligned with numerous tactile suction cups having a specialized geometry and cavity. This study employed fused deposition modeling (FDM) printers to model and fabricate octopus-inspired suction cups. We examined different aspect ratios and shapes of cavities, such as cuboids, cylinders, and octopus suction cup cavities, while maintaining similar outer geometry. The compressive test proved that the inside cavity plays a significant role in enhancing strength due to stress distribution and is represented as a robust biomimetic design. The finite element analysis (FEA) is also developed to corroborate the experimental findings. The statistical validation of the experimental results is achieved through a multilinear regression equation. Our findings demonstrate that the naturally evolved octopus structure exhibits superior compressive strength, enhanced energy absorption, and the ability to generate negative pressure, rendering it highly suitable for gripping, suction, and shock-absorption applications.

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Biodesign as a Tool to Achieve Sustainable Construction Through Additive Manufacturing

Ortega Del Rosario,

Castaño,

Chen Austin

2024

Environmental Footprints and Eco-Design of Products and Processes

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3D-Printed Biomimetic Hierarchical Nacre Architecture: Fracture Behavior and Analysis

Cited by 11 publications

References 70 publications

Recent advancement and trends in the development of membranes having bactericidal attributes via direct ink writing

Recent advancement and trends in the development of membranes having bactericidal attributes via direct ink writing

Unleashing Enhanced Compressive Strength: 3D Printed Octopus-Inspired Suction Cups Using Topological Engineering

Biodesign as a Tool to Achieve Sustainable Construction Through Additive Manufacturing

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