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

Funano, Shun‐ichi; Ota, Noriyasu; Tanaka, Yo

doi:10.1039/d1lc00058f

Cited by 30 publications

(12 citation statements)

References 60 publications

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“…Recent years have also witnessed an increase in the use of glass, particularly borosilicate glass, as a material for MEMS fabrication. It possesses exceptional properties that are well suited for this technology, especially in terms of proper hardness for suppressing channel wall deformation, superior optical transparency, chemical, and biological inertness, surpassing optical transparency and insulating properties, high solvent compatibility, and the possibility of surface modification for facilitating liquid flow [75,76]. However, the manufacturing of glass microfluidic devices is significantly expensive and time-consuming, involving complex, multi-step processes that combine different techniques, tools, and equipment [77].…”

Section: Methodsmentioning

confidence: 99%

Microelectromechanical Systems (MEMS) for Biomedical Applications

Chircov

Grumezescu

2022

Micromachines

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The significant advancements within the electronics miniaturization field have shifted the scientific interest towards a new class of precision devices, namely microelectromechanical systems (MEMS). Specifically, MEMS refers to microscaled precision devices generally produced through micromachining techniques that combine mechanical and electrical components for fulfilling tasks normally carried out by macroscopic systems. Although their presence is found throughout all the aspects of daily life, recent years have witnessed countless research works involving the application of MEMS within the biomedical field, especially in drug synthesis and delivery, microsurgery, microtherapy, diagnostics and prevention, artificial organs, genome synthesis and sequencing, and cell manipulation and characterization. Their tremendous potential resides in the advantages offered by their reduced size, including ease of integration, lightweight, low power consumption, high resonance frequency, the possibility of integration with electrical or electronic circuits, reduced fabrication costs due to high mass production, and high accuracy, sensitivity, and throughput. In this context, this paper aims to provide an overview of MEMS technology by describing the main materials and fabrication techniques for manufacturing purposes and their most common biomedical applications, which have evolved in the past years.

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Section: Methodsmentioning

confidence: 99%

Microelectromechanical Systems (MEMS) for Biomedical Applications

Chircov

Grumezescu

2022

Micromachines

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“…A typical setup consists of three coaxially assembled basic modules: an injection tube, a transition tube, and a collection tube. Although the cost of glass is low, the process of fabricating chips from glass is time-consuming and labor-intensive [ 24 , 25 , 26 ]. In addition, the extremely impermeable properties of glass and silicon limit on-chip cell culture [ 27 ].…”

Section: Microfluidic Devicementioning

confidence: 99%

Recent Advances in Drug Delivery System Fabricated by Microfluidics for Disease Therapy

2022

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Traditional drug therapy faces challenges such as drug distribution throughout the body, rapid degradation and excretion, and extensive adverse reactions. In contrast, micro/nanoparticles can controllably deliver drugs to target sites to improve drug efficacy. Unlike traditional large-scale synthetic systems, microfluidics allows manipulation of fluids at the microscale and shows great potential in drug delivery and precision medicine. Well-designed microfluidic devices have been used to fabricate multifunctional drug carriers using stimuli-responsive materials. In this review, we first introduce the selection of materials and processing techniques for microfluidic devices. Then, various well-designed microfluidic chips are shown for the fabrication of multifunctional micro/nanoparticles as drug delivery vehicles. Finally, we describe the interaction of drugs with lymphatic vessels that are neglected in organs-on-chips. Overall, the accelerated development of microfluidics holds great potential for the clinical translation of micro/nanoparticle drug delivery systems for disease treatment.

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“…25 Recently, a water-droplet bonding method was developed to realize room-temperature glass bonding via H 2 O as the bonding agent. 6 A pressure endurance of more than 600 kPa within 6 h of bonding was sufficient for cell cultivation, but far from suitable for high-pressure nanofluidic scenarios. Overall, these methods are not cost-effective, nano-structure friendly, or robust enough for the mass production of glass nanofluidics.…”

Section: Introductionmentioning

confidence: 99%

“…polydimethylsiloxane, PDMS) with low stiffness and water permeability, fused-silica glass substrates are extensively used for nanofluidic devices because they offer overwhelming advantages including chemical inertness, higher values of Young's modulus and light transmission, and can be used to fabricate nanostructures with high resolution and avoid fluid leaching and evaporation. 6,7 To achieve nanofluidic devices successfully, it is paramount to construct and hermetically seal channels via assembling glass substrates with nanostructures. To date, low-temperature bonding has provided a desirable assembly solution with the merits of protecting high-temperature sensitive functional components immobilized in channels such as biomolecules, electrodes, sensors, waveguides, optical components, etc.…”

Section: Introductionmentioning

confidence: 99%

Room-temperature bonding of glass chips via PTFE-assisted plasma modification for nanofluidic applications

et al. 2023

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

Abstract: A simple method, using only neutral detergent for surface cleaning, produces reversible glass–glass bonding to enable use of a glass microfluidic device repeatedly and enable switching a microchannel from closed for cell cultivation to open for cell recovery.

Cited by 30 publications

References 60 publications

Microelectromechanical Systems (MEMS) for Biomedical Applications

Microelectromechanical Systems (MEMS) for Biomedical Applications

Recent Advances in Drug Delivery System Fabricated by Microfluidics for Disease Therapy

Room-temperature bonding of glass chips via PTFE-assisted plasma modification for nanofluidic applications

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