Low-temperature direct bonding of glass nanofluidic chips using a two-step plasma surface activation process

Xu, Yan; Wang, Chenxi; Dong, Yiyang; Li, Lixiao; Jang, Kyung‐In; Mawatari, Kazuma; Suga, Tadatomo; Kitamori, Takehiko

doi:10.1007/s00216-011-5574-2

Cited by 84 publications

(73 citation statements)

References 24 publications

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“…We utilized low‐temperature bonding in order to avoid heat‐associated destruction of functional molecules during thermal bonding. This method enables glass‐glass bonding at 25–100 °C by oxygen plasma surface activation involving fluorine.…”

Section: Resultsmentioning

confidence: 99%

“…After permanent glass bonding, patterning is difficult in the closed channels, which are not easily accessible from the outside. Low‐temperature (25–100 °C) bonding methods recently developed by our group avoid thermal destruction because the principle is based on chemical bonding between silanol groups without heat; however, the oxygen plasma irradiation surface activation process decreases the activity of modified functional molecules.…”

Section: Introductionmentioning

confidence: 99%

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Extended Nanofluidic Immunochemical Reaction with Femtoliter Sample Volumes

Shirai

Mawatari

Kitamori

2013

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The growing need to optimize immunoassay performance driven by interest in analyzing individual cells has resulted in a decrease in the amount of sample required. Miniaturized immunoassays that use ultra-small femtoliter to attoliter sample volumes, a range known as the extended nanospace, can satisfy this analytical need; however, capturing every targeted molecule without loss in extended nanochannels for subsequent detection remains challenging. This is the first report of a successful extended nanofluidics-based quantitative immunochemical reaction capable of high capture efficiency using a femtoliter-scale sample volume. A novel patterning method using a photolithographic technique with vacuum ultraviolet light and low-temperature (100 °C) bonding enables patterning of functional groups for antibody immobilization before bonding, resulting in an immunochemical reaction space of only 86 fL. Reaction rate analyses indicate a decrease in the required sample volume to 810 fL and improvement in the limit of detection to 3 zmol, 5-6 orders of magnitude better than possible with the microfluidic immunoassay format. Highly efficient (near 100%) immunochemical reactions on a seconds time scale are possible due to the nm-scale diffusion length, which should be advantageous for the analysis of ultra-low-volume samples.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Extended Nanofluidic Immunochemical Reaction with Femtoliter Sample Volumes

Shirai

Mawatari

Kitamori

2013

Small

Self Cite

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“…Before the activation treatment, all samples were initially passed through a proprietary multistage bath cleaning process. First, the glass pieces were rinsed in acetone and methanol with ultrasonic assistance for 8 Notably, during each process, we carefully washed the samples under running DI water to remove any residue from the previous procedure and then kept the samples in DI water for the next procedure.…”

Section: Methodsmentioning

confidence: 99%

Low temperature direct bonding of silica glass via wet chemical surface activation

Mai

Yang

2015

RSC Adv.

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Silica glass pairs were directly bonded by wet chemical surface activation at a low temperature. A smooth joint interface with no voids and micro cracks was obtained with the assistance of a 250 C heat treatment and a pressure of $30 MPa, and the excellent transmittance of the bonded pair was demonstrated by UV-Vis absorptions. This new method can tolerate a silica glass surface roughness as high as 6 nm. A demo chip with a microfluidic channel was also prepared by this method. A modified model for the glass-to-glass bonding mechanism is proposed based on the surface and interface characterization. Raman scattering analysis showed that Si-O-Si linkages at the silica glass surface were broken, and colloid-like hydrolyzed layers formed on the glass surface after the activation treatment. TEM and EELS results revealed that the 3D glass structure of the Si-O-Si linkages formed again at the interface of the directly bonded silica glass pairs after low-temperature annealing.

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“…[58][59][60][61][62][63][64][65] Many well-written review articles have been published on the subject of droplet flow. 9,[66][67][68][69][70][71][72][73][74][75][76][77][78][79][80][81] In this review, parallel two-phase flow 6,[82][83][84][85] is considered with respect to the roles of liquid interfaces for the sake of simplified physical descriptions.…”

Section: ·1 Two-phase Flowmentioning

confidence: 99%