FDM 3D Printing of High-Pressure, Heat-Resistant, Transparent Microfluidic Devices

Romanov, Valentin; Samuel, Reichel; Chaharlang, Marzieh; Jafek, Alexander; Frost, Adam; Gale, Bruce K.

doi:10.1021/acs.analchem.8b02356

Cited by 104 publications

(86 citation statements)

References 28 publications

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“…However, it is a popular material used in AM and has been proven to be effective in FDM [56]. A study on microfluidic devices has shown the use of PLA through FDM to manufacture medical devices, with less than 1% variability shown between replicate prints [69]. PLA stents have also been produced through FDM, with a printing temperature of 220 • C [70].…”

Section: Poly(lactic Acid)mentioning

confidence: 99%

Fused Deposition Modelling as a Potential Tool for Antimicrobial Dialysis Catheters Manufacturing: New Trends vs. Conventional Approaches

et al. 2019

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The rising rate of individuals with chronic kidney disease (CKD) and ineffective treatment methods for catheter-associated infections in dialysis patients has led to the need for a novel approach to the manufacturing of catheters. The current process requires moulding, which is time consuming, and coated catheters used currently increase the risk of bacterial resistance, toxicity, and added expense. Three-dimensional (3D) printing has gained a lot of attention in recent years and offers the opportunity to rapidly manufacture catheters, matched to patients through imaging and at a lower cost. Fused deposition modelling (FDM) in particular allows thermoplastic polymers to be printed into the desired devices from a model made using computer aided design (CAD). Limitations to FDM include the small range of thermoplastic polymers that are compatible with this form of printing and the high degradation temperature required for drugs to be extruded with the polymer. Hot-melt extrusion (HME) allows the potential for antimicrobial drugs to be added to the polymer to create catheters with antimicrobial activity, therefore being able to overcome the issue of increased rates of infection. This review will cover the area of dialysis and catheter-related infections, current manufacturing processes of catheters and methods to prevent infection, limitations of current processes of catheter manufacture, future directions into the manufacture of catheters, and how drugs can be incorporated into the polymers to help prevent infection.

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Section: Poly(lactic Acid)mentioning

confidence: 99%

Fused Deposition Modelling as a Potential Tool for Antimicrobial Dialysis Catheters Manufacturing: New Trends vs. Conventional Approaches

et al. 2019

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“…Unless these parameters can be reversed, it seems likely that the next generation of devices will be engineered using 2-photon lithography and/or additive manufacturing. Alongside the drive for optical transparency, which is already becoming a mainstream demand for devices, 73,74 the critical features that will drive the development of this technology for bottom-up synthetic biology are; Resolution: The size of bilayer encased compartments that can be engineered on-chip is directly related to the dimensions of the microchannels. This combined with growing interest in constructing multicompartment and networked model assemblies at biorepresentative length-scales, places huge emphasis on resolution when fabricating RP devices.…”

Section: Future Perspectivementioning

confidence: 99%

New Directions for Artificial Cells Using Prototyped Biosystems

et al. 2019

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Microfluidics has been shown to be capable of generating a range of single-and multi-compartment vesicles and bilayer delineated droplets that can be assembled in 2D and 3D. These model systems are becoming increasingly recognized as powerful biomimetic constructs for assembling tissue models, engineering therapeutic delivery systems and for screening drugs. One bottleneck in developing this technology is the time, expertise and equipment required for device fabrication. This has led to interest across the microfluidics community in using rapid prototyping to engineer microfluidic devices from Computer Aided Design (CAD) drawings. We highlight how this rapid prototyping revolution is transforming the fabrication of microfluidic devices for bottom-up synthetic biology. We provide an outline of the current landscape and present how advances in the field may give rise to the next generation of multifunctional biodevices, particularly with Industry 4.0 on the horizon. Successfully developing this technology and making it open-source could pave the way for a new generation of citizen-led science, fueling the possibility that the next multibillion dollar start-up could emerge from an attic or a basement.

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“…На процесс печати влияют многие факторы, такие как длительность печати, посторонние тепловые воздействия на объект печати и на само устройство и т.д. Проанализировав выводы Romanov [6] , Sun [8] и Wang [9], принимаем за исходное, что процесс протекает одинаково в плоскостях l1, l2, l3 при рекомендованной скорости печати.…”

Section: рис 5 таблица с температурными режимами экспериментовunclassified

Additive Technologies for Prototyping. Control Geometric Characteristics of Parts From Abs Plastic to Determine the Original Dimensions for Printing

Tignibidin¹,

Takayuk²

2018

DSMM

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FDM 3D Printing of High-Pressure, Heat-Resistant, Transparent Microfluidic Devices

Cited by 104 publications

References 28 publications

Fused Deposition Modelling as a Potential Tool for Antimicrobial Dialysis Catheters Manufacturing: New Trends vs. Conventional Approaches

Fused Deposition Modelling as a Potential Tool for Antimicrobial Dialysis Catheters Manufacturing: New Trends vs. Conventional Approaches

New Directions for Artificial Cells Using Prototyped Biosystems

Additive Technologies for Prototyping. Control Geometric Characteristics of Parts From Abs Plastic to Determine the Original Dimensions for Printing

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