Chung, Philip, Heller, J Alex, Etemadi, Mozziyar, Ottoson, Paige E, Liu, Jonathan A, Rand, Larry, and Roy, Shuvo
Journal of visualized experiments : JoVE, iss 88
Vagina, Humans, Silicone Elastomers, Equipment and Supplies, Computer-Aided Design, Female, Printing, Three-Dimensional, Bioengineering, Issue 88, liquid injection molding, reaction injection molding, molds, 3D printing, fused deposition modeling, rapid prototyping, medical devices, low cost, low volume, rapid turnaround time, Cognitive Sciences, Biochemistry and Cell Biology, and Psychology
Biologically inert elastomers such as silicone are favorable materials for medical device fabrication, but forming and curing these elastomers using traditional liquid injection molding processes can be an expensive process due to tooling and equipment costs. As a result, it has traditionally been impractical to use liquid injection molding for low-cost, rapid prototyping applications. We have devised a method for rapid and low-cost production of liquid elastomer injection molded devices that utilizes fused deposition modeling 3D printers for mold design and a modified desiccator as an injection system. Low costs and rapid turnaround time in this technique lower the barrier to iteratively designing and prototyping complex elastomer devices. Furthermore, CAD models developed in this process can be later adapted for metal mold tooling design, enabling an easy transition to a traditional injection molding process. We have used this technique to manufacture intravaginal probes involving complex geometries, as well as overmolding over metal parts, using tools commonly available within an academic research laboratory. However, this technique can be easily adapted to create liquid injection molded devices for many other applications.
Chepelev, Leonid, Giannopoulos, Andreas, Tang, Anji, Mitsouras, Dimitrios, and Rybicki, Frank J
3D printing in medicine, vol 3, iss 1
3D printing, Additive manufacturing, Data integration, Freeform fabrication, Medicine, Rapid prototyping, Standards, and Terminology
Background:Medical 3D printing is expanding exponentially, with tremendous potential yet to be realized in nearly all facets of medicine. Unfortunately, multiple informal subdomain-specific isolated terminological 'silos' where disparate terminology is used for similar concepts are also arising as rapidly. It is imperative to formalize the foundational terminology at this early stage to facilitate future knowledge integration, collaborative research, and appropriate reimbursement. The purpose of this work is to develop objective, literature-based consensus-building methodology for the medical 3D printing domain to support expert consensus. Results:We first quantitatively survey the temporal, conceptual, and geographic diversity of all existing published applications within medical 3D printing literature and establish the existence of self-isolating research clusters. We then demonstrate an automated objective methodology to aid in establishing a terminological consensus for the field based on objective analysis of the existing literature. The resultant analysis provides a rich overview of the 3D printing literature, including publication statistics and trends globally, chronologically, technologically, and within each major medical discipline. The proposed methodology is used to objectively establish the dominance of the term "3D printing" to represent a collection of technologies that produce physical models in the medical setting. We demonstrate that specific domains do not use this term in line with objective consensus and call for its universal adoption. Conclusion:Our methodology can be applied to the entirety of medical 3D printing literature to obtain a complete, validated, and objective set of recommended and synonymous definitions to aid expert bodies in building ontological consensus.
Hong, Chris J., Giannopoulos, Andreas A., Hong, Brian Y., Witterick, Ian J., Irish, Jonathan C., Lee, John, Vescan, Allan, Mitsouras, Dimitrios, Dang, Wilfred, Campisi, Paolo, de Almeida, John R., and Monteiro, Eric
The Laryngoscope. Sept, 2019, Vol. 129 Issue 9, p2045, 8 p.
Santana Roma, Galdric, Alitany, Ayman, Giménez Mateu, Luís, Redondo Domínguez, Ernesto, Universitat Politècnica de Catalunya. Departament d'Expressió Gràfica Arquitectònica I, and Universitat Politècnica de Catalunya. ADR&M - Arquitectura, Disseny: Representació i Modelatge
Àrees temàtiques de la UPC::Informàtica::Hardware, Printers (Data processing systems), Three-dimensional imaging, NURBS (computer program), Cultural heritage, Reverse engineering, The roshan, stereophotogrammetry, Rapid Prototyping, CNC-Milling, NURBS Modeling, B-Spline interpolation, 3D printing, Impressores (Ordinadors), Imatges tridimensionals, and NURBS (programes d'ordinador)
Nueva metodología de proceso de mecanizado 3D, mediante fresadora CNC o impresora 3D, a partir de una nube de puntos procedente de un escaneado 3D mediante estereofotogrametría, con la finalidad de optimizar el acabado y la métrica superficial obtenida, en función de los parámetros finales de la fresa o del extrusor, mediante una aplicación de algoritmos, directamente sobre la nube de puntos sin pasar por una triangulación, aplicando interpolación de B-Splines, evitando la “poliedrización” del resultado. Esta metodología se ensaya sobre la reproducción de un panel ornamental del roshan como técnica complementaria de la conservación del patrimonio. New methodology for 3D machining process by CNC milling or 3D printer, in order to optimize the finishing of metric surface obtained from point clouds that generated by 3D scan using stereo-photogrammetry. Based on the final parameters of the milling cutter or extruder, we developed an application of algorithms directly on the point clouds without going through triangulation, using B-spline interpolation, avoiding