Qianying Guo scite author profile

Rapid screening of infected individuals from a large population is an effective means in epidemiology, especially to contain outbreaks such as COVID-19. The gold standard assays for COVID-19 diagnostics are mainly based on the reverse transcription polymerase chain reaction, which mismatches the requirements for wide-population screening due to time-consuming nucleic acid extraction and amplification procedures. Here, we report a direct nucleic acid assay by using a graphene field-effect transistor (g-FET) with Y-shaped DNA dual probes (Y-dual probes). The assay relies on Y-dual probes modified on g-FET simultaneously targeting ORF1ab and N genes of SARS-CoV-2 nucleic acid, enabling high a recognition ratio and a limit of detection (0.03 copy μL –1 ) 1–2 orders of magnitude lower than existing nucleic acid assays. The assay realizes the fastest nucleic acid testing (∼1 min) and achieves direct 5-in-1 pooled testing for the first time. Owing to its rapid, ultrasensitive, easily operated features as well as capability in pooled testing, it holds great promise as a comprehensive tool for population-wide screening of COVID-19 and other epidemics.

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Ultra-fast single-crystal polymerization of large-sized covalent organic frameworks

Peng

Guo

Song

et al. 2021

Nat Commun

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In principle, polymerization tends to produce amorphous or poorly crystalline materials. Efficiently producing high-quality single crystals by polymerization in solvent remains as an unsolved issue in chemistry, especially for covalent organic frameworks (COFs) with highly complex structures. To produce μm-sized single crystals, the growth time is prolonged to >15 days, far away from the requirements in practical applications. Here, we find supercritical CO2 (sc-CO2) accelerates single-crystal polymerization by 10,000,000 folds, and produces two-dimensional (2D) COF single crystals with size up to 0.2 mm within 2~5 min. Although it is the fastest single-crystal polymerization, the growth in sc-CO2 leads to not only the largest crystal size of 2D COFs, but also higher quality with improved photoconductivity performance. This work overcomes traditional concept on low efficiency of single-crystal polymerization, and holds great promise for future applications owing to its efficiency, industrial compatibility, environmental friendliness and universality for different crystalline structures and linkage bonds.

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A comprehensive nano-interpenetrating semiconducting photoresist toward all-photolithography organic electronics

Chen

Wang

et al. 2021

Sci. Adv.

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Owing to high resolution, reliability, and industrial compatibility, all-photolithography is a promising strategy for industrial manufacture of organic electronics. However, it receives limited success due to the absence of a semiconducting photoresist with high patterning resolution, mobility, and performance stability against photolithography solution processes. Here, we develop a comprehensive semiconducting photoresist with nano-interpenetrating structure. After photolithography, nanostructured cross-linking networks interpenetrate with continuous phases of semiconducting polymers, enabling submicrometer patterning accuracy and compact molecular stacking with high thermodynamic stability. The mobility reaches the highest values of photocrosslinkable organic semiconductors and maintains almost 100% after soaking in developer and stripper for 1000 min. Owing to the comprehensive performance, all-photolithography is achieved, which fabricates organic inverters and high-density transistor arrays with densities up to 1.1 × 105 units cm−2 and 1 to 4 orders larger than conventional printing processes, opening up a new approach toward manufacturing highly integrated organic circuits and systems.

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Self-Controlled Growth of Covalent Organic Frameworks by Repolymerization

Yang

Guo

et al. 2020

Chem. Mater.

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The growth of covalent organic frameworks (COFs) normally goes through a fast polymerization process, which quickly forms amorphous powder and then slowly crystallizes to obtain nanometer-sized crystals. Until now, it is still a challenge to modulate the growth process of COFs, which hampers the controllable synthesis for practical applications. Here, we develop a repolymerization strategy which realizes the self-controlled growth of COFs for the first time. COFs powder is used as starting material that can slowly decompose and release monomers and oligomers. At a self-established equilibrium state of reversible polymerization− decomposition−repolymerization reactions, the monomers and oligomers controllably repolymerize to form a thin crystalline COF film on substrates. The resulting COF film can be directly used as the sensing interface of graphene transistor sensors, which detect NH 3 down to 100 ppt, showing the great potential of this strategy in future applications.

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Short-wavelength ultraviolet dosimeters based on DNA nanostructure-modified graphene field-effect transistors

Wang

Guo

et al. 2021

Chem. Commun.

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Qianying Guo

Direct SARS-CoV-2 Nucleic Acid Detection by Y-Shaped DNA Dual-Probe Transistor Assay

Ultra-fast single-crystal polymerization of large-sized covalent organic frameworks

A comprehensive nano-interpenetrating semiconducting photoresist toward all-photolithography organic electronics

Self-Controlled Growth of Covalent Organic Frameworks by Repolymerization

Short-wavelength ultraviolet dosimeters based on DNA nanostructure-modified graphene field-effect transistors

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