Microfluidic system manufacturing by direct laser writing for the generation and characterization of microdroplets

Álvarez-Martínez, J. Ulises; Medina-Cázares, Orlando M.; Alcaraz, Maria Eugenia Soto; Castañeda-Priego, Ramón; Gutiérrez-Juárez, G.; Castro-Beltrán, Rigoberto

doi:10.1088/1361-6439/ac628d

Cited by 4 publications

(2 citation statements)

References 63 publications

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“…The manufacture of microfluidic devices typically involves assorted processes, such as structural design, finite element simulation, mask creation, mold crafting, replication, chip alignment, and bonding. Surface chemical bonding plays an essential role in the facile assembly of microfluidic devices between PDMS and thermoplastic materials [62][63][64]. The group led by Lee underscored a method that involves the use of chemical surface modification at ambient temperature and atmospheric pressure for the assembly of microfluidic systems [65].…”

Section: Chemical Bondingmentioning

confidence: 99%

Microfluidic biosensors: exploring various applications through diverse bonding methods

Yang,

Zhu

2024

J. Micromech. Microeng.

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Biological sensors are widely applied in agriculture, biomedicine, food, healthcare, environmental monitoring, water quality, forensics, drug development, etc.. Particularly the utilization of microfluidic technology has become prevalent in the development and manufacturing of biosensors for miniaturization, automation, and integration. Microfluidic biosensors have distinct advantages, including enhanced diffusive timescales, controlled concentration gradients, high throughput, high precision fluid manipulation, stable reaction environments and high sensitivity. From the perspective of sensor fabrication, bonding remains the crucial pathway in the pursuit of integrating microfluidic technology with biosensor chips, while various bonding methods are employed across different application domains. This paper delves into the classification, progress, and challenges associated with these bonding methods corresponding with various microfluidic biosensors in diverse applications. The review presented herein highlights the latest advancements in microfluidic biosensors based on diverse bonding methods, underscoring their significant application prospects and developmental potential within these fields.

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Section: Chemical Bondingmentioning

confidence: 99%

Microfluidic biosensors: exploring various applications through diverse bonding methods

Yang,

Zhu

2024

J. Micromech. Microeng.

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“…Additionally, the short processing time reduces the risk of oxidation for the metallic inks, [25] negating the need for an inert gas atmosphere or vacuum setup during the process. [35] Laser printing has been used to fabricate printed electronics, [36,37] as well as for tissue engineering, [38,39] microfluidics, [40,41] magnetic sensors, [42,43] and holographic elements. [44,45] Material properties such as microstructure, crystallographic structure, and magnetic and electric conductivity can be manipulated by controlling the laser and scanning parameters, affecting the induced sintering process by modifying the temperature reached and the cooling rate.…”

Section: Introductionmentioning

confidence: 99%

Development of Magnetocaloric Microstructures from Equiatomic Iron–Rhodium Nanoparticles through Laser Sintering

et al. 2023

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Pronounced magnetocaloric effects are typically observed in materials that often contain expensive and rare elements and are therefore costly to mass produce. However, they can rather be exploited on a small scale for miniaturized devices such as magnetic micro coolers, thermal sensors, and magnetic micropumps. Herein, a method is developed to generate magnetocaloric microstructures from an equiatomic iron–rhodium (FeRh) bulk target through a stepwise process. First, paramagnetic near‐to‐equiatomic solid‐solution FeRh nanoparticles (NPs) are generated through picosecond (ps)‐pulsed laser ablation in ethanol, which are then transformed into a printable ink and patterned using a continuous wave laser. Laser patterning not only leads to sintering of the NP ink but also triggers the phase transformation of the initial γ‐ to B2‐FeRh. At a laser fluence of 246 J cm−2, a partial (52%) phase transformation from γ‐ to B2‐FeRh is obtained, resulting in a magnetization increase of 35 Am2 kg−1 across the antiferromagnetic to ferromagnetic phase transition. This represents a ca. sixfold enhancement compared to previous furnace‐annealed FeRh ink. Finally, herein, the ability is demonstrated to create FeRh 2D structures with different geometries using laser sintering of magnetocaloric inks, which offers advantages such as micrometric spatial resolution, in situ annealing, and structure design flexibility.

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Recent developments toward microfluidic point-of-care diagnostic sensors for viral infections

Zarean Mousaabadi,

Talebi Vandishi,

Kermani

et al. 2023

TrAC Trends in Analytical Chemistry

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Microfluidic system manufacturing by direct laser writing for the generation and characterization of microdroplets

Cited by 4 publications

References 63 publications

Microfluidic biosensors: exploring various applications through diverse bonding methods

Microfluidic biosensors: exploring various applications through diverse bonding methods

Development of Magnetocaloric Microstructures from Equiatomic Iron–Rhodium Nanoparticles through Laser Sintering

Recent developments toward microfluidic point-of-care diagnostic sensors for viral infections

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