Trends in 3D Printing Processes for Biomedical Field: Opportunities and Challenges

Ghilan, Alina; Chiriac, Aurica P.; Niţă, Loredana E.; Rusu, Alina Gabriela; Neamţu, Iordana; Chiriac, Vlad Mihai

doi:10.1007/s10924-020-01722-x

Cited by 124 publications

(59 citation statements)

References 214 publications

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“…Unlike traditional manufacturing, AM offers novel avenues and has demonstrated the ability to fabricate complex structures with improved accuracy (Sing et al, 2016). The numbers of AM applications, especially in the medical implant manufacturing sector, have quickly increased and are expected to revolutionize health care (Emelogu et al, 2016;Willemsen et al, 2019;Fan et al, 2020;Ghilan et al, 2020). Previous studies have explored the use of CAD modeling and AM to improve both surgical planning and manufacture of customized implants with effective results (Jardini et al, 2014;Dodier et al, 2020;Tel et al, 2020).…”

Section: Discussionmentioning

confidence: 99%

Design and Additive Manufacturing of a Biomimetic Customized Cranial Implant Based on Voronoi Diagram

et al. 2021

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Reconstruction of cranial defects is an arduous task for craniomaxillofacial surgeons. Additive manufacturing (AM) or three-dimensional (3D) printing of titanium patient-specific implants (PSIs) made its way into cranioplasty, improving the clinical outcomes in complex surgical procedures. There has been a significant interest within the medical community in redesigning implants based on natural analogies. This paper proposes a workflow to create a biomimetic patient-specific cranial prosthesis with an interconnected strut macrostructure mimicking bone trabeculae. The method implements an interactive generative design approach based on the Voronoi diagram or tessellations. Furthermore, the quasi-self-supporting fabrication feasibility of the biomimetic, lightweight titanium cranial prosthesis design is assessed using Selective Laser Melting (SLM) technology.

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Section: Discussionmentioning

confidence: 99%

Design and Additive Manufacturing of a Biomimetic Customized Cranial Implant Based on Voronoi Diagram

et al. 2021

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“…The workflow shows the steps involved in manufacturing a CL by a 3D printer, beginning from 3D CAD model to the final printing of CL. [ 81 ] i) The CAD model can be developed by SolidWorks, ii) The 3D‐printing tool was used for adding support and creating G‐code or any other file suitable for the specific 3D printer, iii) 3D‐printing using a DLP printer where the print bed is dipped in the resin and UV light is applied to the resin from bottom through a transparent film, iv) Multiple CLs up to 12 printed at a time and attached on the print bed. v) The final CL washed and removed from the print bed which then can be polished and stored.…”

Section: D Printingmentioning

confidence: 99%

Prospects for Additive Manufacturing in Contact Lens Devices

et al. 2020

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Additive manufacturing (3D printing) has the ability to architect structures at microscale, giving rise to the development of functional contact lenses (CLs) with inbuilt sensing capabilities. 3D printing technology enables fabrication of CLs without surface geometry restrictions. Spherical, nonspherical, symmetric, and asymmetric lenses can be manufactured in an integrated production process. Advantages of 3D printing over conventional techniques include fast and easy production, one‐step manufacturing, and no post processing such as grinding or polishing. In addition, and most significantly, 3D printing can create chambers within the wall of the lenses by taking the advantage of computer‐aided modeling and layer‐by‐layer deposition of the materials. These inbuilt chambers can be used for loading drugs and sensing elements. The computer‐aided design modeling can allow for manufacturing of patient‐specific CLs. This article focuses on the 3D‐printing approaches and the challenges faced in fabricating CLs. 3D‐printing technology as a technique for manufacturing of CLs is discussed, in addition to the manufacturing challenges and the possible solutions to overcome the obstacles.

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“…and structural properties (e.g., three-dimensional (3D) architecture, surface topography, porosity, etc.) plays a key role in healthcare applications (e.g., tissue engineering and regenerative medicine) [ 37 , 38 ]. Biocompatibility and biodegradability are other properties which have to be considered to limit any rejection or toxicity issues.…”

Section: Introductionmentioning

confidence: 99%

Short-Pulse Lasers: A Versatile Tool in Creating Novel Nano-/Micro-Structures and Compositional Analysis for Healthcare and Wellbeing Challenges

et al. 2021

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Driven by flexibility, precision, repeatability and eco-friendliness, laser-based technologies have attracted great interest to engineer or to analyze materials in various fields including energy, environment, biology and medicine. A major advantage of laser processing relies on the ability to directly structure matter at different scales and to prepare novel materials with unique physical and chemical properties. It is also a contact-free approach that makes it possible to work in inert or reactive liquid or gaseous environment. This leads today to a unique opportunity for designing, fabricating and even analyzing novel complex bio-systems. To illustrate this potential, in this paper, we gather our recent research on four types of laser-based methods relevant for nano-/micro-scale applications. First, we present and discuss pulsed laser ablation in liquid, exploited today for synthetizing ultraclean “bare” nanoparticles attractive for medicine and tissue engineering applications. Second, we discuss robust methods for rapid surface and bulk machining (subtractive manufacturing) at different scales by laser ablation. Among them, the microsphere-assisted laser surface engineering is detailed for its appropriateness to design structured substrates with hierarchically periodic patterns at nano-/micro-scale without chemical treatments. Third, we address the laser-induced forward transfer, a technology based on direct laser printing, to transfer and assemble a multitude of materials (additive structuring), including biological moiety without alteration of functionality. Finally, the fourth method is about chemical analysis: we present the potential of laser-induced breakdown spectroscopy, providing a unique tool for contact-free and space-resolved elemental analysis of organic materials. Overall, we present and discuss the prospect and complementarity of emerging reliable laser technologies, to address challenges in materials’ preparation relevant for the development of innovative multi-scale and multi-material platforms for bio-applications.

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Trends in 3D Printing Processes for Biomedical Field: Opportunities and Challenges

Cited by 124 publications

References 214 publications

Design and Additive Manufacturing of a Biomimetic Customized Cranial Implant Based on Voronoi Diagram

Design and Additive Manufacturing of a Biomimetic Customized Cranial Implant Based on Voronoi Diagram

Prospects for Additive Manufacturing in Contact Lens Devices

Short-Pulse Lasers: A Versatile Tool in Creating Novel Nano-/Micro-Structures and Compositional Analysis for Healthcare and Wellbeing Challenges

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