A compression transmission device for the evaluation of bonding strength of biocompatible microfluidic and biochip materials and systems

Kratz, Sebastian Rudi Adam; Bachmann, Barbara; Spitz, Sarah; Höll, Gregor; Eilenberger, Christoph; Goeritz, H.; Ertl, Peter; Rothbauer, Mario

doi:10.1038/s41598-020-58373-0

Cited by 7 publications

(6 citation statements)

References 40 publications

(45 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In comparison to the thermal bond strength of 0.31 MPa of our developed dual‐curing material, the commercially available dual‐curing material OSTEMER 322 shows an increased bond strength of 1.0 MPa. [ 50 ] However, the thermal bond strengths of common thermoplastic materials for microfluidic devices such as PS–PS (0.38 MPa), [ 51 ] PMMA–PMMA (0.19 MPa), [ 52 ] or PET–PET (0.25 MPa) [ 53 ] as well as an acrylate/epoxy‐based dual‐curing adhesive (0.26 MPa) [ 54 ] are in the same range as our developed material. Thus, the adhesive‐free dry bonding of the presented dual‐curing system provides a simple method for fabrication of microfluidic devices with suitable bond strength.…”

Section: Resultsmentioning

confidence: 99%

High‐Resolution 3D Printing of Dual‐Curing Thiol‐Ene/Epoxy System for Fabrication of Microfluidic Devices for Bioassays

Böcherer,

Li,

Rein

et al. 2024

Adv Funct Materials

View full text Add to dashboard Cite

The customized processing of polymer materials in the microscale by high‐resolution 3D printing provides an easy access to advanced applications in the fields of optics, microfluidics, tissue engineering, and life science. However, the 3D printing of enclosed structures in the scale of tens of microns such as closed microfluidic channels remains a challenge as channel structures often are clogged by residual cured resin. Dual‐curing systems based on off‐stoichiometric thiol‐ene and thiol‐ene/epoxy chemistry are well‐known for adhesive‐free bonding in the fabrication of cast or injection molded microfluidic devices. Herein, the first high‐resolution stereolithography 3D printing of a dual‐curing thiol‐ene/epoxy system in the microscale for the fabrication of customized microfluidic devices is presented. In the first curing step, by high‐resolution 3D printing open microfluidic structures are produced. Consecutively, the microchannels are sealed by adhesive‐free dry bonding upon thermal initiation, producing well‐controlled structures with channel sizes down to 80 µm. Before bonding, the intermediate material allows for tailored surface modification with biotin, which allows for consecutive immobilization of various biomolecules. A DNA‐bioassay with specific patterning is shown in the sealed chip. The presented work paves the way toward the fabrication of customized microfluidic devices for a large range of specific bioassays.

show abstract

Section: Resultsmentioning

confidence: 99%

High‐Resolution 3D Printing of Dual‐Curing Thiol‐Ene/Epoxy System for Fabrication of Microfluidic Devices for Bioassays

Böcherer,

Li,

Rein

et al. 2024

Adv Funct Materials

View full text Add to dashboard Cite

show abstract

“…These methods, however, entail the risk of introducing new substances that can alter biocompatibility, surface energy, monomer leaching and optical properties. [25,26] The uneven coating and unwanted filling of microchannels by the interfacing materials are further obstacles commonly associated with such methods. [27] With the recent emergence of microphysiological systems (MPS) that are based on compartmentalized perfused devices of often hybrid nature, [28,29] the need for appropriate back-end processing techniques has been brought to the spotlight.…”

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Robust and Seamless Integration of Thiol‐Ene‐Epoxy Thermosets with Thermoplastics and Glass as Hybrid Microfluidic Devices Suitable for Drug Studies

Harris,

Kaveh,

Kemas

et al. 2024

Adv Materials Inter

View full text Add to dashboard Cite

Facile, durable and biocompatible integration of hybrid Lab‐on‐a‐Chip devices has remained an important challenge in microengineering. Here, the robust and seamless integration of off‐stoichiometry thiol‐ene‐epoxy (OSTE+) thermosets with a diverse range of thermoplastic and glass materials is demonstrated. While direct bonding offers sturdy proprieties for the majority of the material hybrids (up to 1.5 MPa), further surface priming enhances the bonding strength for those of lower surface energy (up to seven‐fold). Using microfluidic devices with a unique configuration of chambers and microchannels down to 100 µm, the impact of various bonding methods on their fluidic functionality is further shown. To investigate the utility of hybrid devices for pharmacological and toxicological studies, both pristine and primed devices are benchmarked against polydimethylsiloxane (PDMS) with regard to cell biocompatibility and drug absorption. While being on par with PDMS in terms of cell viability, pristine OSTE+ devices show an 11‐fold lower absorption of hydrophobic drug molecules. Although surface priming enhances the bonding strength, it compromises other criteria in device performance and biological applications. Combined, results demonstrate a novel integration approach for facile manufacturing of hybrid microfluidic devices using a material toolbox suitable for cell and pharmaceutical studies.

show abstract

“…However, being a PDMS/Glass device means that the device may delaminate and will require another round of plasma to be covalently reattached. [18] We then check the size-sorting device for three applications: detecting parasite eggs, microplastics, and zooplankton from water bodies. The eggs can also be identified on a less than 10 Euro ESP32 microscope that was developed during this research (Figure S3 and S4).…”

Section: Introductionmentioning

confidence: 99%

Step-by-step : A microfluidic (PDMS) staircase device for size sorting microparticles down to 25 µm using a 3D-printed mold

Velders

Lieshout

Brienen

et al. 2023

Preprint

View full text Add to dashboard Cite

Microparticles are ubiquitous and span from living matter to microplastics to inorganic materials. Their detection and identification must be more accessible and time efficient. Microfluidic devices can filter microparticles from liquids, but fabricating microfluidics with lateral resolutions of a few tens of microns is complex, lengthy, and outside the reach of most scientists researching microparticles. In this article, we show how to use height features in a channel instead of relying on lateral elements for separating particles. The height features can be as small as 25 µm, along the Z axis, using consumer-grade 3D printers. We show the potential of such microfluidic devices for size-sorting parasite eggs such as Schistosoma haematobium, microplastics, and zooplankton.

show abstract

A compression transmission device for the evaluation of bonding strength of biocompatible microfluidic and biochip materials and systems

Cited by 7 publications

References 40 publications

High‐Resolution 3D Printing of Dual‐Curing Thiol‐Ene/Epoxy System for Fabrication of Microfluidic Devices for Bioassays

High‐Resolution 3D Printing of Dual‐Curing Thiol‐Ene/Epoxy System for Fabrication of Microfluidic Devices for Bioassays

Robust and Seamless Integration of Thiol‐Ene‐Epoxy Thermosets with Thermoplastics and Glass as Hybrid Microfluidic Devices Suitable for Drug Studies

Step-by-step : A microfluidic (PDMS) staircase device for size sorting microparticles down to 25 µm using a 3D-printed mold

Contact Info

Product

Resources

About