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1. Structural determinants driving homoserine lactone ligand selection in the Pseudomonas aeruginosa LasR quorum-sensing receptor

   https://doi.org/10.1073/pnas.1817239116  

   McCready, Amelia R.; Paczkowski, Jon E.; Henke, Brad R.; Bassler, Bonnie L. (December 2018, Proceedings of the National Academy of Sciences)

   Quorum sensing is a cell–cell communication process that bacteria use to orchestrate group behaviors. Quorum sensing is mediated by signal molecules called autoinducers. Autoinducers are often structurally similar, raising questions concerning how bacteria distinguish among them. Here, we use thePseudomonas aeruginosaLasR quorum-sensing receptor to explore signal discrimination. The cognate autoinducer, 3OC₁₂homoserine lactone (3OC₁₂HSL), is a more potent activator of LasR than other homoserine lactones. However, other homoserine lactones can elicit LasR-dependent quorum-sensing responses, showing that LasR displays ligand promiscuity. We identify mutants that alter which homoserine lactones LasR detects. Substitution at residue S129 decreases the LasR response to 3OC₁₂HSL, while enhancing discrimination against noncognate autoinducers. Conversely, the LasR L130F mutation increases the potency of 3OC₁₂HSL and other homoserine lactones. We solve crystal structures of LasR ligand-binding domains complexed with noncognate autoinducers. Comparison with existing structures reveals that ligand selectivity/sensitivity is mediated by a flexible loop near the ligand-binding site. We show that LasR variants with modified ligand preferences exhibit altered quorum-sensing responses to autoinducers in vivo. We suggest that possessing some ligand promiscuity endows LasR with the ability to optimally regulate quorum-sensing traits. 

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2. Improved Hydrogen Sensitivity and Selectivity in PdO with Metal-Organic Framework Membrane

   https://doi.org/10.1149/1945-7111/abc0ac  

   Gardner, David W.; Xia, Yong; Fahad, Hossain M.; Javey, Ali; Carraro, Carlo; Maboudian, Roya (October 2020, Journal of The Electrochemical Society)

   Metal-organic frameworks (MOFs) are highly designable porous materials and are recognized for their exceptional selectivity as chemical sensors. However, they are not always suitable for incorporation with existing sensing platforms, especially sensing modes that rely on electronic changes in the sensing material (e.g., work-function response or conductometric response). One way that MOFs can be utilized is by growing them as a porous membrane on a sensing layer and using the MOF to affect the electronic structure of the sensing layer. In this paper, a proof-of-concept for electronic modulation with MOFs is demonstrated. A PdO nanoparticle sensing layer on a chemical-sensitive field-effect-transistor is made more sensitive to a reducing gas, hydrogen, and less sensitive to oxidizng molecules, like H₂S and NO₂, by growing a layer of the MOF “ZIF-8” over the nanoparticles. The proposed mechanism is supported by X-ray photoelectron spectroscopy showing that the ZIF-8 membrane partially reduces the PdO sensing layer. 

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3. Reversible and Ultrasensitive Detection of Nitric Oxide Using a Conductive Two‐Dimensional Metal–Organic Framework

   https://doi.org/10.1002/anie.202419869  

   Noh, Hyuk‐Jun; Pennington, Doran_L; Seo, Jeong‐Min; Cline, Evan; Benedetto, Georganna; Baek, Jong‐Beom; Hendon, Christopher_H; Mirica, Katherine_A (December 2024, Angewandte Chemie International Edition)

   Abstract This paper describes the use of a highly crystalline conductive 2D copper₃(hexaiminobenzene)₂(Cu₃(HIB)₂) as an ultrasensitive (limit of detection of 1.8 part‐per‐billion), highly selective, reversible, and low power chemiresistive sensor for nitric oxide (NO) at room temperature. The Cu₃(HIB)₂‐based sensors retain their sensing performance in the presence of humidity, and exhibit strong signal enhancement towards NO over other highly toxic reactive gases, such as NO₂, H₂S, SO₂, NH₃, CO, as well as CO₂. Mechanistic investigations of the Cu₃(HIB)₂‐NO interaction through spectroscopic analyses and density functional theory revealed that the Cu‐bis(iminobenzosemiquinoid) moieties serve as the binding sites for NO sensing, while the Ni‐bis(iminobenzosemiquinoid) MOF analog shows no noticeable response to NO. Overall, these findings provide a significant advance in the development of crystalline metal‐bis(iminobenzosemiquinoid)‐based conductive 2D MOFs as highly sensitive, selective, and reversible sensing materials for the low‐power detection of toxic gases. 

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4. Freestanding BaTiO ₃ ‐Au Vertically Aligned Nanocomposite toward Flexible Multi‐Sensing Platform

   https://doi.org/10.1002/adfm.202418004  

   Tsai, Benson_Kunhung; Huang, Jialong; Yu, Ya‐Ching; Lee, Meng_Hao; Stegman, Benjamin_Thomas; Flores, Emiliano_Joseph; Tong, Patrick_Zhang; Xu, Ke; Zhou, Shiyu; Shen, Jianan; et al (January 2025, Advanced Functional Materials)

   Abstract Flexible and wearable sensors show enormous potential for personalized healthcare devices by real‐time monitoring of an individual's health. Typically, a single functional material is selected for one sensor to sense a particular physical signal while multiple materials will be selected for multi‐mode sensing. Vertically aligned nanocomposites (VANs) have recently demonstrated various material combinations and novel coupled multifunctionalities that are hard to achieve in any single‐phase material alone, including multiphase multiferroics, magneto‐optic coupling, and strong magnetic and optical anisotropy. Integrating these novel VANs into wearable sensors shows enormous potential in multi‐mode sensing owing to their multifunctional nature. In this work, the transfer of VANs onto polydimethylsiloxane as a novel flexible chemical and pressure sensor is demonstrated. For this demonstration, the classical BaTiO₃‐Au VAN with combined plasmonic and piezoelectric properties is used to demonstrate a multi‐sensing mechanism. A thin water‐soluble buffer of Sr₃Al₂O₆serves as a buffer layer for the epitaxial growth and transfer process. The electrical output based on the piezoelectric responses and identifying 4‐mercaptobenzoic acid by surface‐enhanced Raman spectroscopy reveal great potential for free‐standing VANs in a wearable multifunctional sensing platform. 

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5. High Sensitivity and Ultra‐Broad‐Range NH ₃ Sensor Arrays by Precise Control of Step Defects on The Surface of Cl ₂ ‐Ndi Single Crystals

   https://doi.org/10.1002/advs.202308036  

   Lu, Bin; Stolte, Matthias; Liu, Dong; Zhang, Xiaojing; Zhao, Lihui; Tian, Liehao; Frisbie, C. Daniel; Würthner, Frank; Tao, Xutang; He, Tao (April 2024, Advanced Science)

   Abstract Vapor sensors with both high sensitivity and broad detection range are technically challenging yet highly desirable for widespread chemical sensing applications in diverse environments. Generally, an increased surface‐to‐volume ratio can effectively enhance the sensitivity to low concentrations, but often with the trade‐off of a constrained sensing range. Here, an approach is demonstrated for NH₃sensor arrays with an unprecedentedly broad sensing range by introducing controllable steps on the surface of an n‐type single crystal. Step edges, serving as adsorption sites with electron‐deficient properties, are well‐defined, discrete, and electronically active. NH₃molecules selectively adsorb at the step edges and nearly eliminate known trap‐like character, which is demonstrated by surface potential imaging. Consequently, the strategy can significantly boost the sensitivity of two‐terminal NH₃resistance sensors on thin crystals with a few steps while simultaneously enhancing the tolerance on thick crystals with dense steps. Incorporation of these crystals into parallel sensor arrays results in ppb–to–% level detection range and a convenient linear relation between sheet conductance and semi‐log NH₃concentration, allowing for the precise localization of vapor leakage. In general, the results suggest new opportunities for defect engineering of organic semiconductor crystal surfaces for purposeful vapor or chemical sensing. 

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