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The advantages of 3D printing over traditional manufacturing are numerous and well documented, with the key advantages for scientific research outlined here. (21) 3D printed devices are also finding use in point-of-care applications, (22,23) in the form of all-printed analytical devices, (24−31) which are low-cost and integrate both separation and sensing, including electrochemical (26) and optical techniques. (10−12) In analytical sciences, 3D printing has been extensively used in separation and sensing applications in microfluidics, (13−15) for fabricating immunosensors (15,16) and biosensors, (17−20) and even for ex vivo analyses of neurotransmitters. (4,5) On the structural side, 3D printing has gone beyond instrumentation applications, (6,7) and printing useful one-of-a-kind holders and laboratory appliances (8) or helpful teaching resources (9) and now modular and custom designed reactionware tailored for particular chemical reactions can be produced.
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Once a niche for engineering or hobbies, applications of 3D printings now span from structural to functional with 3D printed parts now actively participating in chemical reactions for catalysis (1−3) and energy storage. Additive manufacturing, more commonly known as 3D printing, has impacted chemistry laboratories at both the teaching and research levels.