Ultrasensitive Detection of Nitrite through Implementation of<i>N</i>-(1-Naphthyl)ethylenediamine-Grafted Cellulose into a Paper-Based Device

Mako, Teresa L.; Levenson, Adelaide M; Levine, Mindy

doi:10.1021/acssensors.0c00291

Cited by 46 publications

(24 citation statements)

References 62 publications

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“…As the base‐catalyzed crosslinking agent, ECH is employed to bind alkali lignin and MCC@Fe 3 O 4 chains. [ 15 ] As the second functional crosslinker, Ca 2+ can construct the internal physical network through forming lignin‐metal complexes (lignin‐Ca 2+ ). [ 16 ] As the reaction proceeding, the Ca 2+ can weld the joints served as a bridge between MCC@Fe 3 O 4 and alkali lignin, which can form a network structures with massive robust joints, making the structure more robust and stable.…”

Section: Resultsmentioning

confidence: 99%

Durable Photoetching Magnetic Biomass‐Based Hydrogel with High Performance

Zhang

et al. 2021

Adv Materials Inter

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Benefiting from the economic raw materials and efficient f abrication process, it is easy to directly scale up the hydrogels for biomedical scaffolds, functional materials, and storage systems. However, it remains challenging to construct stable hydrogel combining photoetching technology with low‐cost, room‐temperature, and low‐pressure fabrication. Here, a novel photoetching microcrystalline cellulose (M C C) @ Fe3O4/lignin‐Ca2+ hydrogel with excellent compressive strength (up to 300 kPa) is reported and its elasticity is well maintained under the temperature (−25–100 °C). Interestingly, the magnetic hydrogel exhibits controllable photoetching patterns based on the photothermal effect of Fe3O4 nanoparticles under near‐infrared irradiation (808 nm), especially in the different circumstances including enclosed space and underwater condition. In addition, the magnetic hydrogel displays the outstanding fire resistance and UV absorption (100%). The photoetching magnetic cellulose‐based hydrogel has great potential toward environmental‐friendly devices and applications in optics, electronics, sensors, and other miniature devices.

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Section: Resultsmentioning

confidence: 99%

Durable Photoetching Magnetic Biomass‐Based Hydrogel with High Performance

Zhang

et al. 2021

Adv Materials Inter

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“…Therefore, we decided that immobilizing the detection reagent would capture the color formed and would allow the flow of more sample over the detection zone, which should improve the performance of the device. This was recently successfully achieved by functionalizing one of the two reagents used in the Griess assay on paper, which resulted in an improvement in the detection limit of nitrite [39]. Functionalizing the detection zone is an equipment-free technique to concentrate the analyte of interest in a certain region by flowing a volume of sample that exceeds what is necessary to satisfy the hydrophilic zone [46].…”

Section: Immobilized Griess Reagentmentioning

confidence: 99%

“…Sulfanilamide (98%, Alfa Aesar-A1300136), citric acid (≥99%, Alfa Aesar-A103950B), sodium nitrate (≥99.5%, Honeywell Fluka-31440), sodium nitrite (≥99%, Honeywell Fluka-31443), and ASTM Type 1 deionized water (resistivity > 18 MΩ/cm, LabChem-LC267405). A real seawater sample from the Sargasso Sea region known for its low nutrient content [2,39,48] was used to see if the ions usually found in seawater have any effect on the performance of the device. This seawater sample was filtered through a 0.2 µm filter to remove any organic matter prior to its use.…”

Section: Reagentsmentioning

confidence: 99%

“…The first is a new composite material, which we developed in [38], which increases the reduction efficiency of nitrate to nitrite. The second is a functionalized paper, one that has an immobilized Griess reagent [39], which allows the passage of a larger volume of sample over the detection zone. Moreover, device architecture plays a major role in paper-based microfluidics.…”

Section: Introductionmentioning

confidence: 99%

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A New Paper-Based Microfluidic Device for Improved Detection of Nitrate in Water

Charbaji

Heidari-Bafroui

Anagnostopoulos

et al. 2020

Sensors

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In this paper, we report a simple and inexpensive paper-based microfluidic device for detecting nitrate in water. This device incorporates two recent developments in paper-based technology suitable for nitrate detection and has an optimized microfluidic design. The first technical advancement employed is an innovative fibrous composite material made up of cotton fibers and zinc microparticles that can be incorporated in paper-based devices and results in better nitrate reduction. The second is a detection zone with an immobilized reagent that allows the passage of a larger sample volume. Different acids were tested—citric and phosphoric acids gave better results than hydrochloric acid since this acid evaporates completely without leaving any residue behind on paper. Different microfluidic designs that utilize various fluid control technologies were investigated and a design with a folding detection zone was chosen and optimized to improve the uniformity of the signal produced. The optimized design allowed the device to achieve a limit of detection and quantification of 0.53 ppm and 1.18 ppm, respectively, for nitrate in water. This accounted for more than a 40% improvement on what has been previously realized for the detection of nitrate in water using paper-based technology.

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“…39 Traditional nitrite ion detection was performed using toxic naphthyl ethylenediamine via colorimetry assay. 40 To avoid the usage of toxic materials, other methods including chromatography, 41 electrochemical techniques 42 and fluorescent technology [43][44][45] have been developed. However, these methods need complicated instruments, tedious detection procedures, and are time-consuming.…”

Section: Introductionmentioning

confidence: 99%