Pedram Parandoush scite author profile

Human bone demonstrates superior mechanical properties due to its sophisticated hierarchical architecture spanning from the nano/microscopic level to the macroscopic. Bone grafts are in high demand due to the rising number of surgeries because of increasing incidence of orthopedic disorders, non‐union fractures, and injuries in the geriatric population. The bone scaffolds need to provide porous matrix with interconnected porosity for tissue growth as well as sufficient strength to withstand physiological loads, and be compatible with physiological remodeling by osteoclasts/osteoblasts. The‐state‐of‐art additive manufacturing (AM) technologies for bone tissue engineering enable the manipulation of gross geometries, for example, they rely on the gaps between printed materials to create interconnected pores in 3D scaffolds. Herein, the authors firstly print hierarchical and porous hydroxyapatite (HAP) structures with interconnected pores to mimic human bones from microscopic (below 10 µm) to macroscopic (submillimeter to millimeter level) by combining freeze casting and extrusion‐based 3D printing. The compression test of 3D printed scaffold demonstrates superior compressive stress (22 MPa) and strain (4.4%). The human mesenchymal stromal cells (MSCs) tests demonstrate the biocompatibility of printed scaffold.

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3D Printing of Ultrahigh Strength Continuous Carbon Fiber Composites

Parandoush

Zhou

Lin

2018

Adv Eng Mater

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3D printing of continuous carbon fiber reinforced thermoplastic (CFRTP) composites is increasingly under development owing to its unparalleled flexibility of manufacturing 3D structures over traditional manufacturing processes. However, key issues, such as weak interlayer bonding, voids between beads and layers, and low volume ratio of carbon fiber, in the mainstream fuse deposition modeling (FDM) and extrusion suppress the applications of these techniques in mission‐critical applications, such as aerospace and defense. This communication reports a novel approach, inspired by laminated object manufacturing (LOM), for 3D printing of continuous CFRTPs using prepreg composite sheets. The prepreg sheets are successively cut based on the sliced CAD geometry, and then bonded layer upon layer using a CO2 laser beam and a consolidation roller system. The void content is low by computed tomography scans and interlaminar bonding strength is as high as conventional autoclave method by lap shear strength tests. The excellent interfacial bonding strength and high volume ratio of continuous carbon fiber contribute to the highest reported tensile strength (668.3 MPa) and flexural strength (591.16 MPa) to date, for all 3D printed CFRTPs. Moreover, the proposed technique also enables controlling the alignment of carbon fiber in printed layers. CFRTPs with unidirectional [0°]s, cross‐ply [0/90°]s, and [0/‐45/0/45°]s fiber reinforcement are produced and evaluated for mechanical properties. The proposed 3D printing method is broadly beneficial for industries requiring high performance and lightweight structural materials with complex geometries.

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Laser assisted additive manufacturing of continuous fiber reinforced thermoplastic composites

et al. 2017

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A review of modeling and simulation of laser beam machining

Parandoush

Hossain

2014

International Journal of Machine Tools and Manufacture

177

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