Journal Articles

Havins, L, Capel, A, Christie, S, Lewis, M, Roach, P (2022) Gradient biomimetic platforms for neurogenesis studies, Journal of Neural Engineering, 19(1), 011001, ISSN: 1741-2560. DOI: 10.1088/1741-2552/ac4639.

Merryweather, D, Moxon, SR, Capel, A, Hooper, NM, Lewis, M, Roach, P (2021) Impact of type-1 collagen hydrogel density on integrin-linked morphogenic response of SH-SY5Y neuronal cells, RSC Advances, 11(52), pp.33124-33135, DOI: 10.1039/d1ra05257h.

Capel, A, Smith, MAA, Taccola, S, Pardo-Figuerez, M, Rimington, R, Lewis, M, Christie, S, Kay, RW, Harris, RA (2021) Digitally driven aerosol jet printing to enable customisable neuronal guidance, Frontiers in Cell and Developmental Biology, 9, 722294, ISSN: 2296-634X. DOI: 10.3389/fcell.2021.722294.

Rimington, R, Fleming, J, Capel, A, Wheeler, P, Lewis, M (2021) Bioengineered model of the human motor unit with physiologically functional neuromuscular junctions, Scientific Reports, 11, 11695, ISSN: 2045-2322. DOI: 10.1038/s41598-021-91203-5.

Turner, MC, Rimington, R, Martin, N, Fleming, J, Capel, A, Hodson, L, Lewis, M (2021) Physiological and pathophysiological concentrations of fatty acids induce lipid droplet accumulation and impair functional performance of tissue engineered skeletal muscle, Journal of Cellular Physiology, 236(10), pp.7033-7044, ISSN: 0021-9541. DOI: 10.1002/jcp.30365.

Sallstrom, N, Capel, A, Lewis, M, Engstrom, D, Martin, S (2020) 3D-printable zwitterionic nano-composite hydrogel system for biomedical applications, Journal of Tissue Engineering, 11, pp.1-11, ISSN: 2041-7314. DOI: 10.1177/2041731420967294.

Fleming, J, Capel, A, Rimington, R, Wheeler, P, Leonard, A, Bishop, N, Davies, O, Lewis, M (2020) Bioengineered human skeletal muscle capable of functional regeneration, BMC Biology, 18(1), 145, DOI: 10.1186/s12915-020-00884-3.

Price, A, Capel, A, Lee, R, Pradel, P, Christie, S (2020) An open source toolkit for 3D printed fluidics, Journal of Flow Chemistry, 11, ISSN: 2062-249X. DOI: 10.1007/s41981-020-00117-2.

Aguilar-Agon, K, Capel, A, Fleming, J, Player, DJ, Martin, N, Lewis, M (2020) Mechanical loading of tissue engineered skeletal muscle prevents dexamethasone induced myotube atrophy, Journal of Muscle Research and Cell Motility, 42, pp.149-159, ISSN: 0142-4319. DOI: 10.1007/s10974-020-09589-0.

Rimington, R, Capel, A, Chaplin, K, Fleming, J, Bandulasena, H, Bibb, R, Christie, S, Lewis, M (2019) Differentiation of bioengineered skeletal muscle within a 3D printed perfusion bioreactor reduces atrophic and inflammatory gene expression, ACS Biomaterials Science & Engineering, 5(10), pp.5525-5538, DOI: 10.1021/acsbiomaterials.9b00975.

Wragg, N, Mosqueira, D, Blokpeol‐Ferreras, L, Capel, A, Player, DJ, Martin, N, Liu, Y, Lewis, M (2019) Development of a 3D tissue-engineered skeletal muscle and bone co‐culture system, Biotechnology Journal, 15(1), 1900106, ISSN: 1860-6768. DOI: 10.1002/biot.201900106.

Fleming, J, Capel, A, Rimington, R, Player, DJ, Stolzing, A, Lewis, M (2019) Functional regeneration of tissue engineered skeletal muscle in vitro is dependent on the inclusion of basement membrane proteins, Cytoskeleton, 76(6), pp.371-382, ISSN: 1949-3584. DOI: 10.1002/cm.21553.

Maradze, D, Capel, A, Martin, N, Lewis, M, Zheng, Y, Liu, Y (2019) In vitro investigation of cellular effects of magnesium and magnesium-calcium alloy corrosion products on skeletal muscle regeneration, Journal of Materials Science and Technology, 35(11), pp.2503-2512, ISSN: 1005-0302. DOI: 10.1016/j.jmst.2019.01.020.

Aguilar-Agon, K, Capel, A, Martin, N, Player, DJ, Lewis, M (2019) Mechanical loading stimulates hypertrophy in tissue-engineered skeletal muscle: Molecular and phenotypic responses, Journal of Cellular Physiology, 234(12), pp.23547-23558, ISSN: 0021-9541. DOI: 10.1002/jcp.28923.

Capel, A, Rimington, R, Fleming, J, Player, DJ, Baker, L, Turner, M, Jones, J, Martin, N, Ferguson, R, Mudera, V, Lewis, M (2019) Scalable 3D printed molds for human tissue engineered skeletal muscle, Frontiers in Bioengineering and Biotechnology, 7, 20, ISSN: 2296-4185. DOI: 10.3389/fbioe.2019.00020.

Smith, JA, Mele, E, Rimington, R, Capel, A, Lewis, M, Silberschmidt, V, Li, S (2019) Polydimethylsiloxane and poly(ether) ether ketone functionally graded composites for biomedical applications, Journal of the Mechanical Behavior of Biomedical Materials, 93, pp.130-142, ISSN: 1751-6161. DOI: 10.1016/j.jmbbm.2019.02.012.

Capel, A, Rimington, R, Lewis, M, Christie, S (2018) 3D printing for chemical, pharmaceutical and biological applications, NATURE REVIEWS CHEMISTRY, 2(12), pp.422-436, ISSN: 2397-3358. DOI: 10.1038/s41570-018-0058-y.

Pardo-Figuerez, MM, Martin, N, Player, DJ, Roach, P, Christie, S, Capel, A, Lewis, M (2018) Controlled arrangement of neuronal cells on surfaces functionalized with micro-patterned polymer brushes, ACS Omega, ISSN: 2470-1343. DOI: 10.1021/acsomega.8b01698.

Rimington, R, Capel, A, Player, DJ, Bibb, R, Christie, S, Lewis, M (2018) Feasibility and biocompatibility of 3D‐printed photopolymerized and laser sintered polymers for neuronal, myogenic, and hepatic cell types, Macromolecular Bioscience, 18(7), 1800113, ISSN: 1616-5187. DOI: 10.1002/mabi.201800113.

Jones, J, Player, DJ, Martin, N, Capel, A, Lewis, M, Mudera, V (2018) An assessment of myotube morphology, matrix deformation, and myogenic mRNA expression in custom-built and commercially available engineered muscle chamber configurations, Frontiers in Physiology, ISSN: 1664-042X. DOI: 10.3389/fphys.2018.00483.

Pardo-Figuerez, MM, Martin, N, Player, DJ, Capel, A, Christie, S, Lewis, M (2017) Neural and aneural regions generated by the use of chemical surface coatings, ACS Biomaterials Science and Engineering, 4(1), pp.98-106, ISSN: 2373-9878. DOI: 10.1021/acsbiomaterials.7b00663.

Rimington, R, Capel, A, Christie, S, Lewis, M (2017) Biocompatible 3D printed polymers via fused deposition modelling direct C₂C₁₂ cellular phenotype in vitro, Lab on a Chip, 17(17), pp.2982-2993, ISSN: 1473-0197. DOI: 10.1039/c7lc00577f.

Capel, AJ, Wright, A, Harding, MJ, Weaver, GW, Li, Y, Harris, RA, Edmondson, S, Goodridge, RD, Christie, SDR (2017) 3D printed fluidics with embedded analytic functionality for automated reaction optimisation, Beilstein Journal of Organic Chemistry, 13, pp.111-119, ISSN: 1860-5397. DOI: 10.3762/bjoc.13.14.

Monaghan, T, Capel, A, Christie, S, Harris, R, Friel, R (2015) Solid-state additive manufacturing for metallized optical fiber integration, Composites Part A: Applied Science and Manufacturing, ISSN: 1359-835X. DOI: 10.1016/j.compositesa.2015.05.032.

Capel, AJ, Edmondson, S, Christie, S, Goodridge, R, Bibb, R, Thurstans, M (2013) Design and additive manufacture for flow chemistry, ISSN: 1473-0197. DOI: 10.1039/C3LC50844G.

Conferences

Rimington, RP, Capel, A, Christie, S, Lewis, M (2016) Materials 3D printed via fused deposition modelling elicit myofibrillar alignment and enhanced differentiation of skeletal muscle cells in-vitro. In 16th Annual Meeting of the Tissue and Cell Engineering Society, London.

Et, MC, Delorme, P, Baron, F, Capel, A (1985) Emploi de mesures d'impedance four la modelisation des accumulateurs nickel - CADMIUM. In 1985 IEEE Power Electronics Specialists Conference (ESA SP-230), pp.123-128, DOI: 10.1109/pesc-esasp.1985.7069786.

Designs

Rimington, R, Capel, A, Fleming, J, Player, D, Turner, M, Baker, L, Martin, N, Ferguson, R, Mudera, V, Jones, J, Lewis, M (Accepted for publication) 500uL Mould FDM.

Rimington, R, Capel, A, Lewis, M, Fleming, J, Baker, L, Player, D, Mudera, V, Jones, J, Ferguson, R, Turner, M, Martin, N (Accepted for publication) 250uL Mould FDM and LS.

Rimington, R, Capel, A, Fleming, J, Lewis, M, Player, D, Mudera, V, Jones, J, Ferguson, R, Turner, M, Martin, N, Baker, L (Accepted for publication) 100uL Mould LS.

Rimington, R, Capel, A, Fleming, J, Player, D, Mudera, V, Jones, J, Ferguson, R, Baker, L, Turner, M, Lewis, M, Martin, N (Accepted for publication) 50uL Mould LS.

Rimington, R, Capel, A, Fleming, J, Player, D, Mudera, V, Jones, J, Martin, N, Turner, M, Baker, L, Lewis, M, Ferguson, R (Accepted for publication) 50uL Mould FDM.

Rimington, R, Capel, A, Fleming, J, Player, D, Mudera, V, Jones, J, Lewis, M, Turner, M, Martin, N, Ferguson, R, Baker, L (Accepted for publication) 50uL FDM removable insert.

Rimington, R, Capel, A, Lewis, M, Fleming, J, Player, D, Baker, L, Turner, M, Jones, J, Mudera, V, Ferguson, R, Martin, N (Accepted for publication) 25uL Mould LS.

Rimington, R, Capel, A, Christie, S, Lewis, M, Bibb, R (Accepted for publication) Integrated 12-well plate Bioreactor.

Rimington, R, Capel, A, Lewis, M, Christie, S, Bibb, R (Accepted for publication) Modular 6-well plate Bioreactor.

Rimington, R, Capel, A, Lewis, M, Christie, S, Bibb, R (Accepted for publication) Integrated Tissue Engineered Perfusion System.

Rimington, R, Capel, A, Lewis, M, Christie, S, Bibb, R (Accepted for publication) Modular Tissue Engineered Perfusion System.

Rimington, R, Capel, A, Bibb, R, Christie, S, Lewis, M (Accepted for publication) Screw Thread.

Rimington, R, Capel, A, Lewis, M, Christie, S, Bibb, R (Accepted for publication) O-ring Mould.

Rimington, R, Capel, A, Lewis, M, Christie, S, Bibb, R (Accepted for publication) Monolayer Perfusion System.

Rimington, R, Capel, A, Lewis, M, Christie, S, Bibb, R (Accepted for publication) Tissue Engineered Skeletal Muscle Scaffold.

Datasets

Merryweather, D, Moxon, S, Capel, A, Hooper, N, Lewis, M, Roach, P (2022) Supplementary information files for Impact of type-1 collagen hydrogel density on integrin-linked morphogenic response of SH-SY5Y neuronal cells, DOI: 10.17028/rd.lboro.19740001.

Rimington, R, Fleming, J, Capel, A, Wheeler, P, Lewis, M (2021) Supplementary information files for: Bioengineered model of the human motor unit with physiologically functional neuromuscular junctions, DOI: 10.17028/rd.lboro.15090168.

Price, A, Capel, A, Lee, R, Pradel, P, Christie, S (2020) Supplementary Information Files for An open source toolkit for 3D printed fluidics, DOI: 10.17028/rd.lboro.15164385.

Aguilar-Agon, K, Capel, A, Fleming, J, Player, DJ, Martin, N, Lewis, M (2020) Supplementary Information Files for Mechanical loading of tissue engineered skeletal muscle prevents dexamethasone induced myotube atrophy, DOI: 10.17028/rd.lboro.15164301.

Sallstrom, N, Capel, A, Lewis, M, Engstrom, D, Martin, S (2019) 3D-printable Zwitterionic Nano-composite Hydrogel System for Biomedical Applications.

Media

Price, A, Capel, A, Christie, S, Lee, R (2020) Rhino 3D Demo.

Other

Price, A, Lee, R, Capel, A, Christie, S (Accepted for publication) Male threaded nut, 1/4-28" (UNF) threaded flangeless male nut with 2.50mm channel bore and a tapered tip to allow for the insertion of feruled tubing. The part is used for connecting tubing inlets and outlets of coiled flow reactors and lines of tubing to various junctions and mixers, the connection is made leak tight through the use of a ferule. Part is to be printed in PLA in an upright orientation. A 0.1mm layer and 100% infill is required along with a 10mm adhesion brim. No support scaffold is required..

Price, A, Lee, R, Capel, A, Christie, S (Accepted for publication) Union connector (CORE), 1/4-28" (UNF) flat bottom, female threaded straight union core with 1.00mm channel bore and integrated inlet/ outlet O-rings. The part is to be used as the chemically resistant channeled core of a straight union connector. The combined Core-shell structure is to be used for unifying two separate lines of tubing via two feruled male threaded nuts. (see 'Union connector (SHELL)' for shell counterpart). Part is to be printed in Polypropylene in horizontal orientation such that both integrated O-rings are facing outward. A 0.1mm layer and 100% infill is required along with a material flow rate of 110%. The part can be integrated into its PLA shell structure by loading both core and shell components into the slicing software, and positioning the core at coordinates X:0, Y:0, Z:1.5. and the shell at X:0, Y:0, Z:0. Once grouped (by selecting both parts, right click and select 'Group Models), the part should be raised 10mm above the build plate and a PLA support scaffold should be generated along with a 10mm PLA adhesion brim..

Price, A, Lee, R, Capel, A, Christie, S (Accepted for publication) Union connector (SHELL), 1/4-28" (UNF) flat bottom, female threaded straight union shell with internal core void. The part is to be used as the rigid threaded housing for the channeled core of a straight union connector. The combined core-shell structure is to be used for unifying two separate lines of tubing via two feruled male threaded nuts. (see 'Union connector (CORE)' for core counterpart). Part is to be printed in PLA in a horizontal orientation such that both threaded extrusions are facing outward. A 0.1mm layer height and 100% infill is required. The part can be impregnated with its PP core structure by loading both core and shell components into the slicing software, and positioning the core at coordinates X:0, Y:0, Z:1.5. and the shell at X:0, Y:0, Z:0. Once grouped (by selecting both parts, right clicking and selecting 'Group Models), the part should be raised 10mm above the build plate and a PLA support scaffold should be generated along with a 10mm PLA adhesion brim. .

Price, A, Lee, R, Capel, A, Christie, S (Accepted for publication) Tee-connector (CORE), 1/4-28" (UNF) flat bottom, female threaded tee-connector core with 1.00mm channel bores and integrated inlet/ outlet O-rings. The part is to be used as the chemically resistant channeled core of a Tee-connector. The combined Core-shell structure is to be used for unifying three separate lines of tubing (two inlets into one outlet) via three feruled male threaded nuts. (see 'Tee-connector (SHELL)' for shell counterpart). Part is to be printed in Polypropylene in horizontal orientation such that all integrated O-rings are visible and facing outward. A 0.1mm layer and 100% infill is required along with a material flow rate of 110%. The part can be integrated into its PLA shell structure by loading both core and shell components into the slicing software, and positioning the core at coordinates X:0, Y:0, Z:1.5. and the shell at X:0, Y:0, Z:0 (ensure all O-rings are aligned with the shell female threads, rotate the core structure along the Z axis accordingly to achieve this). Once grouped (by selecting both parts, right click and select 'Group Models), the part should be raised 10mm above the build plate and a PLA support scaffold should be generated along with a 10mm PLA adhesion brim..

Price, A, Lee, R, Capel, A, Christie, S (Accepted for publication) Tee-connector (SHELL), 1/4-28" (UNF) flat bottom, female threaded tee-connector shell with internal core void. The part is to be used as the rigid threaded housing for the channeled core of a tee-connector. The combined Core-shell structure is to be used for unifying three separate lines of tubing (two inlets into one outlet) via three feruled male threaded nuts. (see 'Tee-connector (CORE)' for core counterpart). Part is to be printed in PLA in a horizontal orientation such that all threaded extrusions are visible and facing outward. A 0.1mm layer height and 100% infill is required. The part can be impregnated with its PP core structure by loading both core and shell components into the slicing software, and positioning the core at coordinates X:0, Y:0, Z:1.5. and the shell at X:0, Y:0, Z:0 (ensure all core O-rings are aligned with the shell female threads, rotate the core structure along the Z axis accordingly to achieve this). Once grouped (by selecting both parts, right clicking and selecting 'Group Models'), the part should be raised 10mm above the build plate and a PLA support scaffold should be generated along with a 10mm PLA adhesion brim..

Price, A, Lee, R, Christie, S, Capel, A (Accepted for publication) Cross connector (CORE), 1/4-28" (UNF) flat bottom, female threaded cross-connector core with 1.00mm channel bores and integrated inlet/ outlet O-rings. The part is to be used as the chemically resistant channeled core of a cross-connector. The combined Core-shell structure is to be used for unifying four separate lines of tubing (three inlets into one outlet) via four feruled male threaded nuts. (see 'cross-connector (SHELL)' for shell counterpart). Part is to be printed in Polypropylene in horizontal orientation such that all integrated O-rings are visible and facing outward. A 0.1mm layer and 100% infill is required along with a material flow rate of 110%. The part can be integrated into its PLA shell structure by loading both core and shell components into the slicing software, and positioning the core at coordinates X:0, Y:0, Z:1.5. and the shell at X:0, Y:0, Z:0 (ensure all O-rings are aligned with the shell female threads, rotate the core structure along the Z axis accordingly to achieve this). Once grouped (by selecting both parts, right click and select 'Group Models), the part should be raised 10mm above the build plate and a PLA support scaffold should be generated along with a 10mm PLA adhesion brim..

Price, A, Lee, R, Capel, A, Christie, S (Accepted for publication) Cross connector (SHELL), 1/4-28" (UNF) flat bottom, female threaded cross-connector shell with internal core void. The part is to be used as the rigid threaded housing for the channeled core of a cross-connector. The combined Core-shell structure is to be used for unifying four separate lines of tubing (three inlets into one outlet) via four feruled male threaded nuts. (see 'cross-connector (CORE)' for core counterpart). Part is to be printed in PLA in a horizontal orientation such that all threaded extrusions are visible and facing outward. A 0.1mm layer height and 100% infill is required. The part can be impregnated with its PP core structure by loading both core and shell components into the slicing software, and positioning the core at coordinates X:0, Y:0, Z:1.5. and the shell at X:0, Y:0, Z:0 (ensure all core O-rings are aligned with the shell female threads, rotate the core structure along the Z axis accordingly to achieve this). Once grouped (by selecting both parts, right clicking and selecting 'Group Models'), the part should be raised 10mm above the build plate and a PLA support scaffold should be generated along with a 10mm PLA adhesion brim..

Price, A, Lee, R, Christie, S, Capel, A (Accepted for publication) Y-connector (CORE), 1/4-28" (UNF) flat bottom, female threaded Y-connector core with 1.00mm channel bores and integrated inlet/ outlet O-rings. The part is to be used as the chemically resistant channeled core of a Y-connector. The combined Core-shell structure is to be used for unifying three separate lines of tubing (two inlets into one outlet) via three feruled male threaded nuts. at 120o angles (see 'Y-connector (SHELL)' for shell counterpart). Part is to be printed in Polypropylene in horizontal orientation such that all integrated O-rings are visible and facing outward. A 0.1mm layer and 100% infill is required along with a material flow rate of 110%. The part can be integrated into its PLA shell structure by loading both core and shell components into the slicing software, and positioning the core at coordinates X:-0.01, Y:-1.27, Z:1.5. and the shell at X:0, Y:0, Z:0 (ensure all O-rings are aligned with the shell female threads, rotate the core structure along the Z axis accordingly to achieve this). Once grouped (by selecting both parts, right clicking and selecting 'Group Models), the part should be raised 10mm above the build plate and a PLA support scaffold should be generated along with a 10mm PLA adhesion brim..

Price, A, Lee, R, Christie, S, Capel, A (Accepted for publication) Y-connector (SHELL), 1/4-28" (UNF) flat bottom, female threaded Y-connector shell with internal core void. The part is to be used as the rigid threaded housing for the channeled core of a Y-connector. The combined Core-shell structure is to be used for unifying three separate lines of tubing (two inlets into one outlet) via three feruled male threaded nuts at 120o angles. (see 'Y-connector (CORE)' for core counterpart). Part is to be printed in PLA in a horizontal orientation such that all threaded extrusions are visible and facing outward. A 0.1mm layer height and 100% infill is required. The part can be impregnated with its PP core structure by loading both core and shell components into the slicing software, and positioning the core at coordinates X:-0.01, Y:-1.27, Z:1.5 and the shell at X:0, Y:0, Z:0 (ensure all core O-rings are aligned with the shell female threads, rotate the core structure along the Z axis accordingly to achieve this). Once grouped (by selecting both parts, right clicking and selecting 'Group Models'), the part should be raised 10mm above the build plate and a PLA support scaffold should be generated along with a 10mm PLA adhesion brim..

Price, A, Lee, R, Christie, S, Capel, A (Accepted for publication) Luer adapter (BODY), Threaded Luer Adapter, male luer taper to female 1/4-28" (UNF) Flat Bottom female thread. The part is to be used as the chemically resistant body of a luer adapter with 1mm channel bore and integrated O-ring. The combined body and threaded insert structure is to be used for coupling a line of tubing to a standard luer-lock mdeical/laboratory grade syringe via a feruled male nut. (see Luer adapter (Insert)' for threaded insert counterpart). Part is to be printed in Polypropylene in an upright orientation. A 0.1mm layer and 100% infill is required along with a material flow rate of 110%. The part can be impregnated with its PLA threaded insert by loading both body and insert components into the slicing software, and positioning the body at coordinates X:0, Y:0, Z:2. and the insert at X:0, Y:0, Z:0. Once grouped (by selecting both parts, right clicking and selecting 'Group Models) a PLA support scaffold should be generated to uphold the 90o central overhang, the PLA support should be printed with an infill of 100% to prevent any surface defects occurring that may lead to leakage during its use. a 10mm PLA adhesion brim should also be generated..

Price, A, Lee, R, Christie, S, Capel, A (Accepted for publication) Luer adapter (INSERT), Threaded Luer Adapter, male luer taper to female 1/4-28" (UNF) Flat Bottom female thread - threaded insert. The part is to be used as the rigid threaded insert of a luer adapter. The combined body and threaded insert structure is to be used for coupling a line of tubing to a standard luer-lock medical/laboratory grade syringe via a feruled male nut. (see Luer adapter (body)' for adapter body counterpart). Part is to be printed in PLA in an upright orientation. A 0.1mm layer and 100% infill is required. The part can be inserted into its PP adapter body by loading both body and insert components into the slicing software, and positioning the body at coordinates X:0, Y:0, Z:2. and the insert at X:0, Y:0, Z:0. Once grouped (by selecting both parts, right clicking and selecting 'Group Models) a PLA support scaffold should be generated to uphold the 90o central overhang, the PLA support should be printed with an infill of 100% to prevent any surface defects occurring that may lead to leakage during its use. a 10mm PLA adhesion brim should also be generated..

Price, A, Capel, A, Lee, R, Christie, S (Accepted for publication) Male Thread Test Board, Test board consisting of five male screw threads based on a 1/4"-28 UNF male thread profile with successively increasing (+0.2mm) Major and Minor diameters. Can be used to define the optimum model dimensions for 3D printed male threads tailored to the users unique print conditions, material and environment..

Price, A, Capel, A, Lee, R, Christie, S (Accepted for publication) Female Thread Test Board, Test board consisting of four female screw threads based on a 1/4"-28 UNF female thread profile with successively increasing (+0.2mm) Major and Minor diameters. Can be used to define the optimum model dimensions for 3D printed female threads tailored to the users unique print conditions, material and environment..

Price, A, Capel, A, Lee, R, Christie, S (Accepted for publication) Print Resolution Test Board, Test board consisting of four sections of positive and negative internal and external extrusions. Can be used to asses the smallest feature limitations of a printer/material combination prior to modelling fluidic channels within a structure..

Price, A, Capel, A, Christie, S, Lee, R, Pradel, P (Accepted for publication) Fluidic Reactor Chip, Grasshopper file (.gh) for modifiable fluidic reactor chip, to be imported into 'Rhino 3D' for quick and easy channel geometry variation..

Price, A, Capel, A, Christie, S, Lee, R (Accepted for publication) Fluidic chip, largest radius, Example fluidic reactor file generated in modelling platform, Rhino 3D. This fluidic reactor has been generated with channel radius (Pipe radius) set at the largest possible value (1.00 mm).

Price, A, Capel, A, Christie, S, Lee, R (Accepted for publication) Fluidic chip, largest length, Example fluidic reactor file generated in modelling platform, Rhino 3D. This fluidic reactor has been generated with channel length (Pipe length) set at the largest possible value (40.00 mm).

Price, A, Capel, A, Lee, R, Christie, S (Accepted for publication) Fluidic chip, Largest Number, Example fluidic reactor file generated in modelling platform, Rhino 3D. This fluidic reactor has been generated with channel number (Pipe number) set at the largest possible value (20 channels).