Monolithic 3D labs- and organs-on-chips obtained by lithography-based ceramic manufacture

Lantada, Andrés Díaz; Romero, Ana Moreno; Schwentenwein, Martin; Jellinek, Christopher; Homa, Johannes; García–Ruiz, Josefa P.

doi:10.1007/s00170-017-0443-6

Cited by 14 publications

(8 citation statements)

References 31 publications

(34 reference statements)

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“…As an example of the aforementioned unhealthy behavior of hMSCs, recent studies have demonstrated how the number of cells adhered is reduced if mitochondria have diminished electron transport and how this is directly linked to the progressive spheroidal configurations, apoptotic behavior, and final detachment [29]. Taking into consideration the biofunctionalization post-process performed by using the hMSCs-CM, we would like to mention that the coating improves hMSCs adhesion up to a 30–40%, when compared to the use of uncoated microsystems, as previous studies by our team have shown [12,23,24,26]. However, the manufactured layers can be also used for culturing other cell types and even hMSCs, just after micro-injection and polishing, without the need for a final biofunctionalization step.…”

Section: Resultsmentioning

confidence: 98%

“…Alternative approaches relying on the combination of multi-scale processes, such as mask-based lithography and high-precision direct laser writing (by two-photon polymerization), also allow for the generation of multi-scale organs-on-chips [25], although their productivity (parts manufactured per time unit) is still far from matching the performance of mass-produced systems by micro-injection molding, as presented here. Nevertheless, in terms of geometrical complexity and integration level [26], additive procedures remain unrivalled, so further synergies between processes may prove highly beneficial.…”

Section: Resultsmentioning

confidence: 99%

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Research on the Methods for the Mass Production of Multi-Scale Organs-On-Chips

et al. 2018

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The success of labs- and organs-on-chips as transformative technologies in the biomedical arena relies on our capacity of solving some current challenges related to their design, modeling, manufacturability, and usability. Among present needs for the industrial scalability and impact promotion of these bio-devices, their sustainable mass production constitutes a breakthrough for reaching the desired level of repeatability in systematic testing procedures based on labs- and organs-on-chips. The use of adequate biomaterials for cell-culture processes and the achievement of the multi-scale features required, for in vitro modeling the physiological interactions among cells, tissues, and organoids, which prove to be demanding requirements in terms of production. This study presents an innovative synergistic combination of technologies, including: laser stereolithography, laser material processing on micro-scale, electroforming, and micro-injection molding, which enables the rapid creation of multi-scale mold cavities for the industrial production of labs- and organs-on-chips using thermoplastics apt for in vitro testing. The procedure is validated by the design, rapid prototyping, mass production, and preliminary testing with human mesenchymal stem cells of a conceptual multi-organ-on-chip platform, which is conceived for future studies linked to modeling cell-to-cell communication, understanding cell-material interactions, and studying metastatic processes.

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Section: Resultsmentioning

confidence: 98%

Section: Resultsmentioning

confidence: 99%

Research on the Methods for the Mass Production of Multi-Scale Organs-On-Chips

et al. 2018

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“…Three-dimensional bioceramic-based microsystems are currently manufactured by additive manufacturing such as lithography-based ceramic manufacturing , and laser sintering . These fabrication methods accelerate fabrication processes and reduce cost and production time .…”

Section: Alternative Cell Contacting Materials In Pdms-based Devicesmentioning

confidence: 99%

Beyond Polydimethylsiloxane: Alternative Materials for Fabrication of Organ-on-a-Chip Devices and Microphysiological Systems

Campbell

Yazbeck

et al. 2020

ACS Biomater. Sci. Eng.

174

175

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Polydimethylsiloxane (PDMS) is the predominant material used for organ-on-a-chip devices and microphysiological systems (MPSs) due to its ease-of-use, elasticity, optical transparency, and inexpensive microfabrication. However, the absorption of small hydrophobic molecules by PDMS and the limited capacity for high-throughput manufacturing of PDMS-laden devices severely limit the application of these systems in personalized medicine, drug discovery, in vitro pharmacokinetic/pharmacodynamic (PK/PD) modeling, and the investigation of cellular responses to drugs. Consequently, the relatively young field of organ-on-a-chip devices and MPSs is gradually beginning to make the transition to alternative, nonabsorptive materials for these crucial applications. This review examines some of the first steps that have been made in the development of organ-on-a-chip devices and MPSs composed of such alternative materials, including elastomers, hydrogels, thermoplastic polymers, and inorganic materials. It also provides an outlook on where PDMS-alternative devices are trending and the obstacles that must be overcome in the development of versatile devices based on alternative materials to PDMS.

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“…However, Bauer et al has designed and produced an affordable FDM printed testing apparatus to detect malaria with a cost efficient [55]. Again, thanks to the pore structure obtained by the lithography-based ceramic manufacturing (LCM) method, LOC acts as a membrane with separating cell culture chambers at different levels, which imitates the typical configuration of transwell assays [56]. Furthermore, in a SLA-based printer, an LOC capable of detecting H2O2 and glucose can be produced under $1 [57].…”

Section: Additive Manufacturing Of Lab On a Chipsmentioning

confidence: 99%

Additive Manufacturing of Microfluidic Lab-on-a-Chip Devices

Eren

ÇUHADAROĞLU

Sezer

2021

International Journal of 3D Printing Technologies and Digital Industry

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Additive manufacturing (AM) technologies, also known as 3D printing, which offer advantages such as design flexibility, short lead time and cost effectiveness compared to traditional production methods, are used in many different areas. With the exponentially increasing technological developments, complex structures at micron level can be produced and used in customized applications. One promising unique application of AM is Lab-on-a-chips (LOCs). These microfluidic devices can effectively be used in laboratory experiments carried out on a very small scale in biomedical, chemistry and clinical cases. Lab-on-chip systems, which are time-consuming, specialization-required, and expensive to produce with traditional 2D microfabrication technologies such as lithography and PDMS-glass bonding, have become easily producible with AM methods. Although there are many different AM methods can be used in 3D printing of microfluidics, Multi Jet Printing (MJP) method is frequently preferred because of its high sensitivity and dimensional accuracy. MJP AM technology is based on spraying photopolymer resins to a layer thickness of down to 16 µm, then curing with UV light. This paper critically reviews relevant methods and materials used for 3D printing of microfluidics, especially for the MJP based technologies. 3D-printed microfluidic chips with various microchannel structures were fabricated using a commercial material jet-based 3D printer (Objet 30 Prime -Stratasys). 3D printed samples were examined for surface roughness and dimensional accuracy by profilometer analysis. In addition to the model material used in the study, the curing wavelengths of various photopolymer resins were determined by spectrophotometer analysis. In line with the data obtained, the removal of the support structures stuck in the micro-channels and the improvement of the surface properties were discussed. The results show that the 3D printing of microfluidics is a promising area for often novel applications.

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Monolithic 3D labs- and organs-on-chips obtained by lithography-based ceramic manufacture

Cited by 14 publications

References 31 publications

Research on the Methods for the Mass Production of Multi-Scale Organs-On-Chips

Research on the Methods for the Mass Production of Multi-Scale Organs-On-Chips

Beyond Polydimethylsiloxane: Alternative Materials for Fabrication of Organ-on-a-Chip Devices and Microphysiological Systems

Additive Manufacturing of Microfluidic Lab-on-a-Chip Devices

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