Reversible bonding of thermoplastic-based microfluidics with freeze-release adhesive

Article Nanoscience & Nanotechnology

Reversible bonding for microfluidic devices with UV release tape

Yin Yao et al.

Summary: A novel reversible bonding method using UV curable release tape is proposed in this study, which offers a higher bonding strength and can be easily debonded with a simple UV exposure process.

MICROFLUIDICS AND NANOFLUIDICS (2022)

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Article Chemistry, Analytical

Recent Advances in Thermoplastic Microfluidic Bonding

Kiran Giri et al.

Summary: This review paper summarizes the bonding processes for thermoplastic microfluidic devices and compares different bonding strategies to assist researchers in finding suitable bonding methods for microfluidic device assembly.

MICROMACHINES (2022)

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Article Materials Science, Multidisciplinary

Low-cost irreversible blue diode laser transmission welding of poly(methyl methacrylate)-based microfluidics

Lu Li et al.

Summary: This study proposes a low-cost PMMA-based microfluidic chip bonding method using blue diode laser transmission welding. Compared with traditional bonding methods, this method achieves higher bonding strength without contaminating the microchannel.

APPLIED PHYSICS A-MATERIALS SCIENCE & PROCESSING (2022)

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Article Engineering, Chemical

Reversible Bonding of Thermoplastic Elastomers for Cell Patterning Applications

Byeong-Ui Moon et al.

Summary: This study introduces a simple method for creating cell migration study patterns using thermoplastic elastomer, demonstrating the robust and reversible bonding of TPE on plastic substrates. The approach allows for cell patterning without damaging the cells and confirms the non-toxicity of TPE material for cell growth.

PROCESSES (2021)

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Article Biochemical Research Methods

A simple and reversible glass-glass bonding method to construct a microfluidic device and its application for cell recovery

Shun-ichi Funano et al.

Summary: This study presents a simple glass-glass bonding method for microfluidic devices, which achieves stronger bonding through a higher density of SiOH on the glass surface cleaned by neutral detergent. The method can withstand pressure over 600 kPa and allows for cell recovery after cultivation in microchannels, significantly improving the productivity and usability of glass microfluidic devices for future applications.

LAB ON A CHIP (2021)

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Article Materials Science, Multidisciplinary