Microstereolithography System Research Articles

Effects on Dimensional Accuracy of Microstereolithographically Machined Parts after Addition of Light Absorber

The paper’s aim is to investigate the influence ofadded light absorber (Tinuvin® 327) on dimension accuracyof three-dimensional (3D) micro-parts manufactured by adynamic mask projection microstereolithography (µSL)system. One of the common problems withstereolithography systems, and particularly with µSL is theuncontrolled cure depth of the UV light when fabricatingdown-facing surfaces. To overcome this problem, lightabsorber is commonly used to control the cure depth. Yetthe influence of light absorber on the dimension accuracy ofmanufactured parts is not fully understood and needs to beinvestigated. This work explores the effect on part accuracyof adding four different concentrations of Tinuvin®327 toPIC-100 acrylate resin without light absorber. A benchmark part has been designed to evaluate the effect of theadded Tinuvin®327 on linear, position, and geometric dimensions. Results show that Tinuvin®327 has significanteffects on part accuracy.

Controlled Mechanical Property Gradients Within a Digital Light Processing Printed Hydrogel-Composite Osteochondral Scaffold.

Tissue engineered scaffolds are needed to support physiological loads and emulate the micrometer-scale strain gradients within tissues that guide cell mechanobiological responses. We designed and fabricated micro-truss structures to possess spatially varying geometry and controlled stiffness gradients. Using a custom projection microstereolithography (μSLA) system, using digital light projection (DLP), and photopolymerizable poly(ethylene glycol) diacrylate (PEGDA) hydrogel monomers, three designs with feature sizes < 200μm were formed: (1) uniform structure with 1MPa structural modulus ( ) designed to match equilibrium modulus of healthy articular cartilage, (2) = 1MPa gradient structure designed to vary strain with depth, and (3) osteochondral bilayer with distinct cartilage ( = 1MPa) and bone ( = 7MPa) layers. Finite element models (FEM) guided design and predicted the local mechanical environment. Empty trusses and poly(ethylene glycol) norbornene hydrogel-infilled composite trusses were compressed during X-ray microscopy (XRM) imaging to evaluate regional stiffnesses. Our designs achieved target moduli for cartilage and bone while maintaining 68-81% porosity. Combined XRM imaging and compression of empty and hydrogel-infilled micro-truss structures revealed regional stiffnesses that were accurately predicted by FEM. In the infilling hydrogel, FEM demonstrated the stress-shielding effect of reinforcing structures while predicting strain distributions. Composite scaffolds made from stiff μSLA-printed polymers support physiological load levels and enable controlled mechanical property gradients which may improve in vivo outcomes for osteochondral defect tissue regeneration. Advanced 3D imaging and FE analysis provide insights into the local mechanical environment surrounding cells in composite scaffolds.

Additively Manufactured 3D Micro-bioelectrodes for Enhanced Bioelectrocatalytic Operation

The drive toward miniaturization of enzyme-based bioelectronics established a need for three-dimensional (3D) microstructured electrodes, which are difficult to implement using conventional manufacturing processes. Additive manufacturing coupled with electroless metal plating enables the production of 3D conductive microarchitectures with high surface area for potential applications in such devices. However, interfacial delamination between the metal layer and the polymer structure is a major reliability concern, which leads to device performance degradation and eventually device failure. This work demonstrates a method to produce a highly conductive and robust metal layer on a 3D printed polymer microstructure with strong adhesion by introducing an interfacial adhesion layer. Prior to 3D printing, multifunctional acrylate monomers with alkoxysilane (-Si-(OCH3)3) were synthesized via the thiol-Michael addition reaction between pentaerythritol tetraacrylate (PETA) and 3-mercaptopropyltrimethoxysilane (MPTMS) with a 1:1 stoichiometric ratio. Alkoxysilane functionality remains intact during photopolymerization in a projection micro-stereolithography (PμSLA) system and is utilized for the sol-gel reaction with MPTMS during postfunctionalization of the 3D printed microstructure to build an interfacial adhesion layer. This leads to the implementation of abundant thiol functional groups on the surface of the 3D printed microstructure, which can act as a strong binding site for gold during electroless plating to improve interfacial adhesion. The 3D conductive microelectrode prepared by this technique exhibited excellent conductivity of 2.2 × 107 S/m (53% of bulk gold) with strong adhesion between a gold layer and a polymer structure even after harsh sonication and an adhesion tape test. As a proof-of-concept, we examined the 3D gold diamond lattice microelectrode modified with glucose oxidase as a bioanode for a single enzymatic biofuel cell. The lattice-structured enzymatic electrode with high catalytic surface area was able to generate a current density of 2.5 μA/cm2 at 0.35 V, which is an about 10 times increase in current output compared to a cube-shaped microelectrode.

Additive manufacturing of yttrium-stabilized tetragonal zirconia: Progressive wall collapse, martensitic transformation, and energy dissipation in micro-honeycombs

For zirconia-based technical ceramics, the unique advantages of micro-architecture geometries combined with the potent mechanical and functional properties have been challenging to implement owing to additive manufacturing restrictions. In this work, we present a stereolithography-based additive manufacturing approach involving slurry development for yttrium-stabilized tetragonal zirconia polycrystals (Y-TZP), followed by printing using a custom-built large-area projection micro-stereolithography system. After post-processing, i.e., polymer burnout and sintering, 98% relative density is reached in the printed Y-TZP parts. Thanks to the good manufacturing quality, the bulk-scale Y-TZP micro-honeycombs are able to display typical stretch-dominated behavior in out-of-plane compression, showing elastic loading (Stage I) and protracted brittle failure of individual walls over a significant strain (Stage II). For a Y-TZP micro-honeycomb consisting of 5 × 4 hexagonal cells with a wall thickness of 300 μm and a cell diameter of 1.40 mm, the energy dissipation density is measured to be 9.45 J/g, substantially higher than other ceramic honeycombs and packings reported earlier. This energy dissipation capability is mostly attributed to the progressive wall collapse seen in Stage II deformation, in which the perimeter walls are preferentially fragmented relative to the interior walls. According to finite element analysis, this phenomenon is a result of the deviation from uniaxial compression and the presence of stress gradients in the perimeter walls. We also find evidence for stress-induced martensitic transformation in the Y-TZP micro-honeycomb after compression, which may be another contributor to the observed energy dissipation capability.

3D-Printed Complex Microstructures with a Self-Sacrificial Structure Enabled by Grayscale Polymerization and Ultrasonic Treatment.

Complex three-dimensional (3D) microstructures are attracting more and more attention in many applications such as microelectromechanical systems, biomedical engineering, new materials, new energy, environmental protection, and wearable electronics. However, fabricating complex 3D microstructures by 3D printing techniques, especially those with long suspended structures, needs to introduce additional supporting structures, which are difficult to be removed. Here, we propose a simple method in which the supporting structures can be easily removed by optimizing their size and the grayscale value working with ultrasonic treatment in ethanol solution. The 3D microstructures and the supporting structures made of the same insoluble materials are fabricated simultaneously by using a projection microstereolithography system with a dynamic mask. The results demonstrate that the supporting structures play a key role in the fabrication of the long suspended structures while they can be easily removed. The removal time decreases with the increase in the height of the supporting microstructures, and the breaking force and shearing force of the supporting structures increase with the increase in their grayscale and the diameter. In addition, theory and the multiphysics simulation validate that the stress concentration at the top and the bottom of the supporting structures due to the cavitation from ultrasonic vibration dominates the removal of the supporting structures. Finally, a tree-like structure is precisely fabricated by using our method. The present study provides a new way for the removal of the supporting structures for 3D printed suspended microstructures.

Optimization of the Projection Microstereolithography Process for a Photocurable Biomass-Based Resin.

Biomass materials, an important source of chemical feedstocks, could replace fossil fuels as a resource in the future. The chemical feedstocks from biomass materials are used in many medical and pharmaceutical products and in fuels, chemicals, and functional materials. Biomass materials are expected to be used in biomedical engineering fields, especially due to their low biotoxicity. By the way, most of the demand for bio-application fields is an application targeted for customized production, so a high formability is required for production. Research on three-dimensional (3D) printing technology capable of satisfying these requirements has been ongoing. Manufacturing additives need to be investigated to use biomass materials as a resin or bioink safely for 3D printing, which is a technique widely used in biomedical engineering fields. In this study, a projection microstereolithography (PμSL) system, a 3D printing technique, was made that uses a biomass-based resin. Biomass materials are designed to be photocurable for use in the PμSL process. Various PμSL process parameters were investigated using the biomass-based resin to determine the optimum fabrication conditions for 3D structures. This study demonstrated that a biomass-based resin can be used in the PμSL process. We provide a method for its application in various biomedical engineering fields.

Multi-material microstereolithography using a palette with multicolor photocurable resins

A multi-material microstereolithography system in which multiple photocurable resins are stored on a single glass palette was developed to produce multicolor three-dimensional (3D) models. Multiple photocurable resins with different colors are replaced by moving a linear translational X-stage that supports the glass palette. A Z-stage moves radially to remove the air bubbles that adhere around the 3D model when replacing the resins. The uncurable resin was washed out by sequentially immersing the 3D structure in two tanks containing a cleaning solvent. This makes it possible to produce multicolor 3D models without contaminating the resins and air bubbles.

Development of a multi-material microstereolithography system using resin pallets

Development of a multi-material microstereolithography system using resin pallets

Robust Tracking of a Cost-Effective Micro-Stereolithography System Based on a Compliant Nanomanipulator.

Micro-stereolithography (MSL) has emerged as a promising and challenging technique in micro-/nano-scale additive manufacturing. Besides the requirement of the light source, the motion system requires ultra-high-precision tracking capability to reach the right location for every solidification event. To achieve single-digit micron feature size of the fabrication, we propose a robust control strategy to support a self-developed cost-effective MSL prototype based on a compliant nanomanipulator and a blue light-emitting diode (LED) module. In particular, the nonlinearity and parameter-variation of the compliant manipulator are dealt with by a robust radial basis function (RBF)-based neural network, and the repetitive control (RC) is innovatively integrated with RBF to improve the tracking performance of a closed pattern. Various simulations and real-time experiments are conducted to validate the proposed control strategy. The fabrication of a closed pattern will not begin by turning on the laser source until the tracking error reaches submicrons, and the fabrication results demonstrate that the cost-effective MSL system is capable of fabricating 2.5 µm feature size in a 0.5 mm working range.

Additive manufacturing of self-healing elastomers

Nature excels in both self-healing and 3D shaping; for example, self-healable human organs feature functional geometries and microstructures. However, tailoring man-made self-healing materials into complex structures faces substantial challenges. Here, we report a paradigm of photopolymerization-based additive manufacturing of self-healable elastomer structures with free-form architectures. The paradigm relies on a molecularly designed photoelastomer ink with both thiol and disulfide groups, where the former facilitates a thiol-ene photopolymerization during the additive manufacturing process and the latter enables a disulfide metathesis reaction during the self-healing process. We find that the competition between the thiol and disulfide groups governs the photocuring rate and self-healing efficiency of the photoelastomer. The self-healing behavior of the photoelastomer is understood with a theoretical model that agrees well with the experimental results. With projection microstereolithography systems, we demonstrate rapid additive manufacturing of single- and multimaterial self-healable structures for 3D soft actuators, multiphase composites, and architected electronics. Compatible with various photopolymerization-based additive manufacturing systems, the photoelastomer is expected to open promising avenues for fabricating structures where free-form architectures and efficient self-healing are both desirable.

Development of a two-photon microstereolithography system with an autofocus function

Development of a two-photon microstereolithography system with an autofocus function

Development of a high-resolution microstereolithography system using a blue laser

Development of a high-resolution microstereolithography system using a blue laser

(Invited) Printing 3D Gel Polymer Electrolyte in Li-Ion Microbattery Using Stereolithography

3D li-ion microbattery has gained an increasing importance since the development of microelectromechanical systems (MEMS). Compared with the limited areal capacity for thin-film microbattery, 3D microbattery has the advantage of fully utilizing the limited footprint area without sacrificing the power density. Most of the 3D microbatteries that have been published nowadays require the a) patterning and/or depositing process to define the 3D electrode’s architecture and b) sealing case to ensure the encapsulation for liquid electrolyte. These process increase the difficulty to manufacture 3D microbatteries. UV-curable gel polymer electrolyte (GPE) is one of the routes for creating low-cost, high-yield 3D microbatteries. By using the micro-stereolithography system, GPE can be built into different 3D shapes. Poly (ethylene oxide) (PEO) has been used as the polymer host in the polymer electrolyte. By incorporating lithium salt and organic solvents as plasticizers into the PEO host, a stable and high-conductivity gel electrolyte can be formed. The GPE combines the mechanical properties of a swollen polymer network with the high ion conductivity of the liquid electrolyte. Here we demonstrated a method to manufacture 3D gel polymer electrolyte for microbattery. We characterized the GPE membrane by Electrochemical Impedance Spectroscopy (EIS). The result shows a promising ionic conductivity for the use of solid-state li-ion battery. A half-cell has also been assembled for studying the GPE’s cycle performance. The GPE is then fabricated by stereolithography into different 3D structures. SEM picture shows a nano-porous structure in GPE which facilitates the ion transportation. Assembled with electrode material and current collector, the 3D GPE can be built into a 3D microbattery. The microbattery shows a successful operation for 2 cycles, with a capacity of 1.4mAh cm2.

青色半導体レーザーを用いた内部硬化型マイクロ光造形法の開発とナノインプリントへの応用

In this study, a versatile microstereolithography system using a low-cost blue diode laser was developed. This system enables to generate pinpoint photopolymerization at a focused spot inside a liquid photopolymer like two-photon microfabrication using a femtosecond pulsed laser. It can provide multiscale fabrication owing to the unique property of single-photon polymerization. A microstereolithograpy system using a 405 nm diode laser and galvano-scanner set was constructed. After investigating a suitable photopolymer by absorbance measurement, the fabrication resolution of this system was examined in experiments. In addition, three-dimensional (3D) microstructures including micro lattice models and movable microparts were successfully fabricated. Moreover, additive fabrication of 3D microstructures on patterned films produced by nanoimprinting was demonstrated.

3D-Printable Biodegradable Polyester Tissue Scaffolds for Cell Adhesion

Additive manufacturing, or three-dimensional (3D) printing, has emerged as a viable technique for the production of vascularized tissue engineering scaffolds. In this report, a biocompatible and biodegradable poly(tri(ethylene glycol) adipate) dimethacrylate was synthesized and characterized for suitability in soft-tissue scaffolding applications. The polyester dimethacrylate exhibited highly efficient photocuring, hydrolyzability, and 3D printability in a custom microstereolithography system. The photocured polyester film demonstrated significantly improved cell attachment and viability as compared with controls. These results indicate promise of novel, printable polyesters for 3D patterned, vascularized soft-tissue engineering scaffolds.

RACI Congress Adelaide

The September issue of Aust. J. Chem. contains a selection of papers authored by speakers at the National Congress of the Royal Australian Chemical Institute held in Adelaide, 7–12 December 2014, which integrated all areas of chemistry under one roof in the Adelaide Convention Centre. Neil Vasdev and Steven Liang (Massachusetts General Hospital and Harvard Medical School) present an account on a new avenue to synthesize radiotracers aimed at the eventual ability to radiolabel just about any substance for medicinal purposes. Rainer Koch (University of Oldenburg, Germany), H.-J. Wollweber (University of Marburg, Germany), and the present author (The University of Queensland) report on the synthesis of a-oxo oximes of isoxazolones, pyrazolones, and 1,2,3-triazolone and the elucidation of stereochemical preferences. Toshihide Horikawa (Tokushima University, Japan), Duong Do (The University of Queensland), and their colleagues describe their research on the adsorption of water and methanol on highly graphitized carbon black and activated carbon fibre. John Gladysz and co-workers (Texas A&M University) report on the syntheses of three series of trigonal bipyramidal trans-bis(phosphine) complexes, which can potentially undergo three-fold intramolecular ring closing metatheses to yield gyroscope-like complexes. Frederic Paul, Jean-Francois Halet, and their co-workers (Universite de Rennes 1, France) report a theoretical analysis of electronic structures and optical properties of a series of phenylalkynyl iron complexes, Fe(dppe)(Z-C5Me5). Unexpected hypsochromic shifts of the lower energy absorption bands upon carbon chain lengthening were observed. Bradley Smith et al. (University of Notre Dame, Indiana, USA) report enhanced squaraine rotaxane endoperoxide chemiluminescence in acidic alcohols. The squaraine rotaxane endoperoxides are storable chemiluminescent compounds that undergo a clean cycloreversion reaction, releasing singlet oxygen and emitting near-infrared light when warmed to body temperature. Acidic alcohols such as hexafluoroisopropanol greatly increase the chemiluminescence, which takes place from a squarine excited state. Interlocked rotaxanes are necessay for the effect. Philip E. Thompson (Monash Institute of Pharmaceutical Sciences) and co-workers applied click chemistry to produce linear and cyclic peptide conjugates derived from Fmocpropargyloxyprolines. The conjugates can retain the binding affinity and/or binding conformation of the parent peptide. Frances Separovic (The University of Melbourne) and her co-workers describe C-terminal modifications with hydrazide and alcohol functions that extend the antibacterial activity of a proline-rich peptide towards other Gram-negative species. Furthermore, the new analogues did not show cytotoxicity towards mammalian cells. Jianbo Wang and co-workers at Peking University, China, report Rh-catalyzed cross-coupling of diazoesters with arylstannanes as a first Stille-type coupling using diazo compounds. The reaction is operationally simple, can be carried out under mild conditions, and provides an alternative approach to the synthesis of a-aryl esters. RichardO’Hair (TheUniversity ofMelbourne) et al. report that decarboxylation takes precedence over loss of acetonitrile in silver propiolate complexes of the type [CH3C CCO2Ag2(CH3CN)n] (n1⁄4 1 or 2). Massimiliano Massi and Mark Ogden (Curtin University, Perth), Evan Moore (The University of Queensland), and coworkers have prepared a one-dimensional Eu3þ coordination polymer bearing a-nitrile-substituted b-diketonate and 1,10phenanthroline ligands, which exhibit red emission in the solid state. The sensitization process from the b-diketonate to the Eu3þ is thought to occur via an antenna effect. Aleksey Vasilev (University of Sofia, Bulgaria), Katharina Landfester (Max Planck Institute for Polymer Research, Mainz, Germany), and their co-workers report their work on assembling new two-in-onemerocyanine chromophoreswith a 1,8-naphthalimide core by using the NO2 function as a leaving group in SN-Ar reactions, thus overcoming limitations of the conventional use of halogenide leaving groups. Timothy Long et al. (Virginia Tech, USA) have synthesized a biocompatible, biodegradable, and 3D-printable polyester [poly(tri(ethylene glycol) adipate) dimethacrylate] suitable for building vascularized soft-tissue scaffolding. The polyester exhibited highly efficient photocuring, hydrolyzability, and 3D printability in a custom micro-stereolithography system. The photocured polyester film demonstrated significantly improved cell attachment and viability.

A new Micro-Stereolithography-System based on Diode Laser Curing (DLC)

In this study, a compact diode laser based Micro-Stereolithography (DLC — Diode Laser Curing) system with linear stages has been developed. A suspended cross table was used to position a diode laser with a focusing lens that cures liquid photosensitive resin. Therefore the apparatus does not need complex beam forming and beam guiding, e.g., galvanometer scanner, optic fibers or similar. Only one replaceable focusing lens is needed. A commercial photo-curable resin was adapted by UV-absorber for μ-SLA. To demonstrate the functionality Single-lines were cured with different parameters such as laser power, scan speed and absorber concentration. Afterwards, specimen with simple geometries like edges and circles were cured. Thereby the limitations of roundness and sharp geometries were determined. Finally, 3D-parts are built with optimized curing parameters. The results show that the new Micro-Stereolithography-System, based on diode laser and fast linear stages is suitable for an effective fabrication of 3D micro-parts.

Optimization of rheological properties of photopolymerizable alumina suspensions for ceramic microstereolithography

Microstereolithography (MSL) is a rapid prototyping technique to fabricate complex three-dimensional (3D) structure in the microdomain involving different materials such as polymers and ceramics. The present effort is to fabricate microdimensional ceramics by the MSL system from a non-aqueous colloidal slurry of alumina. This slurry predominantly consists of two phases i.e. sub-micrometer solid alumina particles and non-aqueous reactive difunctional and trifunctional acrylates with inert diluent. The first part of the work involves the study of the stability and viscosity of the slurry using different concentrations of trioctyl phosphine oxide (TOPO) as a dispersant. Based on the optimization, the highest achievable solid loadings of alumina has been determined for this particular colloidal suspension. The second part of the study highlights the fabrication of several micro-dimensional alumina structures by the MSL system.

"ON-AXIS" LINEAR FOCUSED SPOT SCANNING MICROSTEREOLITHOGRAPHY SYSTEM: OPTOMECHATRONIC DESIGN, ANALYSIS AND DEVELOPMENT

Microstereolithography (MSL) is technology of fabrication of three-dimensional (3D) components by using layer-by-layer photopolymerization. Typical design goals of MSL system are: small features, high resolution, high speed of fabrication, and large overall size of component. This paper focuses on design and development of such a system to meet these optomechatronic requirements. We first analyze various optical scanning schemes used for MSL systems along with the proposed scheme via optical simulations and experiments. Next, selection criteria for various subsystems are laid down and appropriate design decisions for the proposed system are made. Further, mechanical design of the scanning mechanism is carried out to meet requirements of high speed and resolution. Finally, system integration and investigation in process parameters is carried out and fabrication of large microcomponent with high resolution is demonstrated. The proposed system would be useful for fabrication of multiple/large microcomponents with high production rate in various applications.

7PM1-D-4 ディップ光ファイバープローブを用いたマイクロ光造形法の提案・実証(7PM1-D OS2 三次元の微細形状創成技術)

Most of microstereolithography systems require a reservoir tank to supply a photopolymer. In addition, thin layers of photopolymer must be formed to make a 3-D structure via layer-by-layer process. Owing to these intrinsic properties, conventional microstereolithography systems need a lot of photopolymer to produce large-scale models. In this study, we intend to develop a novel microstereolithography system using an optical fiber. In this system, a laser beam emitted from the tip of the optical fiber is used to polymerize a photopolymer that kept between the optical fiber and a substrate. Since 3-D structures are fabricated using only a little photopolymer droplet, this system does not require a tank to keep the photopolymer. In addition, 3-D scanning of the tip of the optical fiber enables to add 3-D microstructures to the desired position on a substrate with small amount of photopolymer.