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The original print painting has survived to the present day by changing with the progress of societies and time in the historical process. The development of technology has led to the use of the art of printmaking only for individual or educational purposes in schools. Today, 3D printing production techniques emerge as a new field in both design and production areas. Thanks to the convenience it offers, an alternative art creation tool emerges for designers. Using 3D printing with different disciplines, it creates diversity in the name of design and art. Thanks to the renewed technological developments, it contributes to its development by taking a new field into its sphere of influence every day. In the study, historical and general information about the art of printmaking is included, and the transition processes to 3D printing technology are discussed and compared. In addition, the transition processes and applications to 3D printing systems were examined. Qualitative research method will be used in the research. By making a literature review, the studies on the subject will be discussed and interpreted. This method covers the comparison of original print painting and 3D printing technology by referring to the point they have reached.

"Date originated 07/09/79; Date updated 01/23/80." ; Includes bibliographical references. ; Mode of access: Internet. ; Description based on print resource; title from title page.

G.P.O. sales statement incorrect in publication. ; Caption title. ; Mode of access: Internet.

In 2013, the first gun printed out of plastic by a 3D-printer was successfully fired in the US. This event caused a major media hype about the dangers of being able to print a gun. Law enforcement agencies worldwide were concerned about this development and the potentially huge security implications of these functional plastic guns. As a result, politicians called for a ban of these weapons and a control of 3D-printing technology. This paper reviews the security implications of 3D-printing technology and 3D guns. It argues that current arms control and transfer policies are adequate to cover 3D-printed guns as well. However, while this analysis may hold up currently, progress in printing technology needs to be monitored to deal with future dangers pre-emptively.

Reports prepared by the Subcommittee on Printing (varies slightly) ; [no.1] Reduction of legislative printing costs.--[no.2] Reduction of departmental printing costs. ; Mode of access: Internet.

Intro -- Preface -- Contents -- Contributors -- About the Editors -- Chapter 1: The Shape of Things to Come: Emerging Applications of 3D Printing in Healthcare -- 1 3D Printing: The Next Industrial Revolution -- 1.1 3D Printing in Medicine: An Overview -- 2 Personalised Medicines -- 2.1 Dose Personalisation -- 2.2 Multi-drug Combinations -- 2.3 Tailored Release Profiles -- 2.4 Improved Patient Acceptability -- 2.5 On-demand Printing -- 3 Early Phase Drug Development -- 3.1 Pre-clinical Studies and FIH Trials -- 3.2 Motivations for Using 3DP in Early Phase Drug Development -- 3.2.1 Dose Flexibility -- 3.3 Immediate Manufacture -- 3.4 Reduced Resource Investment -- 3.5 Unique Characteristics -- 4 Conclusion -- References -- Chapter 2: 3D Printing Technologies, Implementation and Regulation: An Overview -- 1 Introduction -- 2 Classification of 3D Printing Technologies -- 2.1 Industrial Applications of 3D Printing -- 2.2 3D Printing Software -- 2.3 Binder Jet Printing -- 2.4 Vat Polymerisation -- 2.4.1 Stereolithography -- 2.5 Powder Bed Fusion -- 2.5.1 Selective Laser Sintering -- 2.6 Material Extrusion -- 2.6.1 Fused Deposition Modelling -- 2.6.2 Semisolid Extrusion -- 2.6.3 Bioprinting -- 2.7 Directed Energy Deposition -- 2.8 Sheet Lamination -- 3 3D Printing Implementation in Healthcare -- 3.1 Rapid Administration and Improved Medicine Access -- 3.2 3D Printing and Wearable Diagnostics -- 3.3 Challenges to 3D Printing Implementation -- 4 Regulatory Requirements -- 4.1 Regulatory Considerations of 3D Printing in Pharmaceutics -- 5 Conclusion -- References -- Chapter 3: Binder Jet Printing in Pharmaceutical Manufacturing -- 1 Introduction -- 2 Binder Jet Methodology -- 3 Pharmaceutical Applications of Binder Jet Printing -- 3.1 Controlled-Release Formulations -- 3.2 Rapidly Dissolving Tablets.

The implications of 3D printing are manifold, with some commentators anticipating permanent market disruption in the massive (and ill-defined) field of small physical things. I begin this paper by asserting that the opportunities afforded by 3D printing are so attractive that it is a mere matter of time before an explosion of use; but that the diffusion of manufacturing to the consumer level is poised to put individual end-users in uncomfortably close contact with intellectual property law. By analogy to the physical CD-distribution model, and the ways in which it broke down in the Napster era, (and with sensitivity to the technological and physical limitations of 3D printing,) I will argue that the copyright landscape as it currently exists is not up to the challenge of managing consumer-grade 3D printing, but that legal clarification as to the copyright eligibility of CAD designs and products can substantially improve this situation. Moreover, I will argue that business should apply copyright delicately to 3D printing. Rather than enforcing copyrights on a similarity basis, industry should instead adopt permissive models of licensing to manage 3D-printable parts, thereby letting go of a part of the market in order to preserve consumer goodwill and develop new markets. Submitted to the Washington State Legislature, Technology and Economic Development Committee. ; https://digitalcommons.law.uw.edu/techclinic/1005/thumbnail.jpg