2017
DOI: 10.3762/bjoc.13.14
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3D printed fluidics with embedded analytic functionality for automated reaction optimisation

Abstract: Additive manufacturing or ‘3D printing’ is being developed as a novel manufacturing process for the production of bespoke micro- and milliscale fluidic devices. When coupled with online monitoring and optimisation software, this offers an advanced, customised method for performing automated chemical synthesis. This paper reports the use of two additive manufacturing processes, stereolithography and selective laser melting, to create multifunctional fluidic devices with embedded reaction monitoring capability. … Show more

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Cited by 43 publications
(23 citation statements)
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“…The possibility of 3D printing (also known as additive manufacturing (AM)) bespoke biologically receptive parts, has driven the increasing application of AM technologies in biological systems. Techniques such as fused deposition modeling (FDM), photopolymerization processes such as stereolithography (SL) and PolyJet printing, in addition to powder‐based particle consolidation laser sintering (LS) technology have all previously been utilized to provide devices/scaffolds for bioengineering . However, the numerous advantages of AM, including design freedom and rapid production without molds or tooling, are currently offset by a lack of fully characterized biocompatible materials …”
Section: Introductionmentioning
confidence: 99%
“…The possibility of 3D printing (also known as additive manufacturing (AM)) bespoke biologically receptive parts, has driven the increasing application of AM technologies in biological systems. Techniques such as fused deposition modeling (FDM), photopolymerization processes such as stereolithography (SL) and PolyJet printing, in addition to powder‐based particle consolidation laser sintering (LS) technology have all previously been utilized to provide devices/scaffolds for bioengineering . However, the numerous advantages of AM, including design freedom and rapid production without molds or tooling, are currently offset by a lack of fully characterized biocompatible materials …”
Section: Introductionmentioning
confidence: 99%
“…[78] Targeted further developments in this field include enabling robotic platforms to handle complete synthetic routes, including work-up and purification steps. [79] …”
Section: One Machine – Many Small Moleculesmentioning
confidence: 99%
“…In early 2017, Christie and co‐workers reported the creation of different multifunctional fluidic devices with embedded reaction monitor capability for the synthesis of heterocycles …”
Section: D Printed Devices In Organic Synthesismentioning
confidence: 99%
“…[48] In early 2017, Christie and co-workers reported the creation of different multifunctional fluidic devices with embedded reaction monitorcapability for the synthesis of heterocycles. [49] Initially,areactor with an inline spectroscopic flow cell printed with SLA technology was realized (circular channels, ID: 1.5 mm, volume:2 .8 mL) and located in the HPLC detector. This reactor, connected to a5mL stainless coil reactor, present at erminal cell designed for the DAD compartment of the HPLC for in-line analysisa nd was used for the determination of the best reaction conditions for the conversion of (R)-carvone to its corresponding semicarbazoneu sing semicarbazide and sodium acetate (Scheme 14).…”
Section: Realization Of 3d Printed Flow Reactorsmentioning
confidence: 99%
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