LEADER 00000cam a2200721Ii 4500 001 on1090547385 003 OCoLC 005 20200717185541.2 006 m o d 007 cr cnu---unuuu 008 190325s2019 enka o 000 0 eng d 015 GBB952329|2bnb 016 7 019309298|2Uk 019 1096293279|a1096478927 020 9781788015745|q(electronic book) 020 1788015746|q(electronic book) 020 9781788017664|q(electronic book) 020 1788017668|q(electronic book) 020 |z1788014405 020 |z9781788014403 035 (OCoLC)1090547385|z(OCoLC)1096293279|z(OCoLC)1096478927 037 5360:5209|bRoyal Society of Chemistry|nhttp://www.rsc.org/ spr 040 UKRSC|beng|erda|epn|cUKRSC|dUIU|dN$T|dEBLCP|dUPM|dOCLCF |dEMU|dYDX|dUKMGB|dCOO|dUKAHL|dOCLCQ|dCNO|dOCLCQ 049 RIDW 050 4 TS171.95|b.G87 2019eb 072 7 TEC|x009010|2bisacsh 072 7 SCI|x013000|2bisacsh 072 7 TDPP|2bicssc 072 7 PN|2bicssc 072 7 TEC|x009070|2bisacsh 082 04 621.988|223 090 TS171.95|b.G87 2019eb 100 1 Gupta, Vipul|c(Neurosurgeon),|0https://id.loc.gov/ authorities/names/n2019189179|eauthor. 245 10 3D printing in chemical sciences :|bapplications across chemistry /|cVioul Gupta, Pavel Nesternko, Brett Paull. 264 1 [England] :|bRoyal Society of Chemistry,|c2019. 300 1 online resource (xi, 250 pages) :|billustrations 336 text|btxt|2rdacontent 337 computer|bc|2rdamedia 338 online resource|bcr|2rdacarrier 340 |gpolychrome|2rdacc 347 text file|2rdaft 505 0 Intro; Half Title; Title; Copyright; Preface; Dedication; Contents; Chapter 1 An Introduction to 3D Printing 1; 1.1 History; 1.2 3D Print Files; 1.3 3D Printing Techniques; 1.3.1 Stereolithography (SL); 1.3.2 Selective Laser Sintering and Melting (SLS/M); 1.3.3 Inkjet Printing; 1.3.4 Fused Deposition Modelling (FDM); 1.4 The 3D Revolution; References; Chapter 2 3D Printing of Micro- and Macro-fluidic Devices 22; 2.1 Introduction; 2.2 Microfluidic Elements; 2.2.1 Droplet-based Microfluidics; 2.2.2 Microfluidic Mixers; 2.2.3 Miscellaneous Microfluidic Elements; 2.3 Microfluidic Valves 505 8 2.3.1 Passive Valves2.3.2 Active Membrane-based Valves; 2.4 Pumps; 2.5 Plug-and-Play Modules; 2.6 Outlook; References; Chapter 3 3D-printed Analytical Detectors 56; 3.1 Introduction; 3.2 Optical Detectors; 3.2.1 Smartphone Optical-sensing Platforms; 3.2.2 Flow-cells for Mixing, Reaction, and Detection; 3.2.3 Miscellaneous Optical Devices; 3.3 Electrochemical Detectors; 3.3.1 Electrochemical Detector Cells; 3.3.2 Printed Electrodes; 3.3.3 Miscellaneous Electrochemical Devices; 3.4 Outlook; References; Chapter 4 3D Printing in Analytical Chemistry Methods and Applications 94; 4.1 Introduction 505 8 4.2 Extraction Methods4.2.1 Solid-phase Extraction; 4.2.2 Centrifugation and Distillation Devices; 4.3 Analytical and Preparative Separations; 4.3.1 Liquid Chromatography; 4.3.2 Gas Chromatography; 4.3.3 Thin-layer Chromatography; 4.4 Mass Spectrometry; 4.4.1 Ambient Ionisation Sources; 4.4.2 Interfaces; 4.5 Integrated Flow-analysis Manifolds and Lab-on-a-chip Devices; 4.6 Outlook; References; Chapter 5 3D Printing in Pharmaceutical Chemistry 138; 5.1 Introduction; 5.2 Development of Pharmaceutical 3D Printing; 5.2.1 Binder Jetting; 5.2.2 Fused Deposition Modelling; 5.2.3 Stereolithography 505 8 5.2.4 PolyJet Printing5.2.5 Selective Laser Sintering; 5.3 Solid Oral Drug Delivery Systems; 5.3.1 Personalised Medicines; 5.3.2 Fast Disintegrating Solid Oral Drug Delivery Systems; 5.3.3 Miscellaneous Solid Oral Drug Delivery Systems; 5.4 Implantable Drug Delivery Systems; 5.5 Transdermal Drug Delivery Systems; 5.6 Outlook; References; Chapter 6 3D Printing in Biochemistry 176; 6.1 Introduction; 6.2 Cell Biology; 6.2.1 Cellular Assays; 6.2.2 Cell Sorting; 6.2.3 Electroporation; 6.3 Molecular Biology; 6.4 In vitro Drug Screening; 6.5 Biocompatibility of 3D Print Materials; 6.6 Outlook 520 3D printing has rapidly established itself as an essential enabling technology within research and industrial chemistry laboratories. Since the early 2000s, when the first research papers applying this technique began to emerge, the uptake by the chemistry community has been both diverse and extraordinary, and there is little doubt that this fascinating technology will continue to have a major impact upon the chemical sciences going forward. This book provides a timely and extensive review of the reported applications of 3D Printing techniques across all fields of chemical science. Describing, comparing, and contrasting the capabilities of all the current 3D printing technologies, this book provides both background information and reader inspiration, to enable users to fully exploit this developing technology further to advance their research, materials and products. It will be of interest across the chemical sciences in research and industrial laboratories, for chemists and engineers alike, as well as the wider science community. 588 0 Print version record. 590 eBooks on EBSCOhost|bEBSCO eBook Subscription Academic Collection - North America 650 0 Three-dimensional printing|0https://id.loc.gov/authorities /subjects/sh2009006799|xIndustrial applications.|0https:// id.loc.gov/authorities/subjects/sh00006117 650 0 Chemistry, Technical.|0https://id.loc.gov/authorities/ subjects/sh85023029 650 7 Three-dimensional printing.|2fast|0https://id.worldcat.org /fast/1748862 650 7 Chemistry, Technical.|2fast|0https://id.worldcat.org/fast/ 853546 655 4 Electronic books. 700 1 Paull, Brett,|0https://id.loc.gov/authorities/names/ nb2011001375|eauthor. 700 1 Nesterenko, Pavel N.,|0https://id.loc.gov/authorities/ names/nb2011001340|eauthor. 776 08 |iPrint version:|aPAULL, BRETT. NESTERENKO, PAVEL. GUPTA, VIPUL.|t3D PRINTING IN CHEMICAL SCIENCES.|d[Place of publication not identified], ROYAL Society OF CHEMISTRY, 2019|z1788014405|w(OCoLC)1044824912 856 40 |uhttps://rider.idm.oclc.org/login?url=http:// search.ebscohost.com/login.aspx?direct=true&scope=site& db=nlebk&AN=2098091|zOnline ebook via EBSCO. Access restricted to current Rider University students, faculty, and staff. 856 42 |3Instructions for reading/downloading the EBSCO version of this ebook|uhttp://guides.rider.edu/ebooks/ebsco 901 MARCIVE 20231220 948 00 |d20200727|cEBSCO|tEBSCOebooksacademic NEW June-July 17 7032|lridw 994 92|bRID