Simultaneous utilization of a bifunctional ruthenium complex as an efficient catalyst for RAFT controlled photopolymerization and a sensing probe for the facile fabrication of an ECL platform
文献情報
Tao Chen, Yuanhong Xu, Zhi Peng, Aihua Li, Jingquan Liu
Ruthenium (Ru)-complex (Ru(bpy)32+) catalyzed reversible addition–fragmentation chain transfer (RAFT) photopolymerization is an attractive technique for preparing polymer-functionalized biomaterials because of its gentle reaction conditions. Until now, negatively charged polymers prepared by this polymerization method have been seldom reported, which should be due to the difficulty in removing the positively charged catalyst Ru(bpy)32+ from the negatively-charged polymer owing to the strong electrostatic attraction between them. However, the difficulty in removing Ru(bpy)32+ from the negatively charged polymer should not always be regarded as just a shortcoming, on the contrary, it can be utilized as an advantage for developing a stable and efficient solid-state electrogenerated chemiluminescence (ECL) sensor. Herein, pyrene-functionalized poly(sodium p-styrene sulfonate) (PSS) was successfully synthesized by RAFT photopolymerization catalyzed via the Ru-complex based photoredox catalyst (Ru(bpy)32+) under visible light (λ = 460 nm). It turned out to be a well-controlled RAFT polymerization as evidenced by 1H NMR and gel permeation chromatography (GPC) analyses. Based on the stable electrostatic attraction of Ru(bpy)32+ with PSS and a non-covalent π–π stacking interaction between the pyrene moiety and the highly oriented pyrolytic graphite surface, a stable and efficient solid-state ECL sensor was successfully fabricated. The as-proposed sensor was investigated using tripropylamine as a representative analyte and a low detection limit of 0.1 nM (S/N ≥ 3) was reached. It also exhibited excellent reproducibility (relative standard deviations of 0.56% for 112 continuous cycles) and long-term stability (about 90% of its preliminary ECL intensity can be retained after intermittent use over a 90-day period).
関連文献
Synthesis and catalytic activity of a chiral periodic mesoporous organosilica (ChiMO)
Bárbara Gigante, Debasish Das, Mercedes Alvaro, Hermenegildo Garcia, Avelino Corma
DOI: 10.1039/B304814D
Large size anion binding with iron(ii) complexes of a 5,5′-disubstituted-2,2′-bipyridine ligand
Biao Wu, Xiao-Juan Yang, Christoph Janiak, Paul Gerhard Lassahn
DOI: 10.1039/B211616B
Stereoselective formation of dinuclear complexes with anomalous CD spectra
Shane G. Telfer, Tomohiro Sato
DOI: 10.1039/B301267K
The role of the counteranion in the cation-π interaction
Christopher A. Hunter, Caroline M. R. Low, Carmen Rotger, Jeremy G. Vinter, Cristiano Zonta
DOI: 10.1039/B300693J
A substituted triaza crown ether as a binding site in DNA conjugates
Stefan Vogel, Katja Rohr, Otto Dahl, Jesper Wengel
DOI: 10.1039/B301100C
Distortion of a cellobio-derived isofagomine highlights the potential conformational itinerary of inverting β-glucosidases
Annabelle Varrot, James Macdonald, Robert V. Stick, Gavin Pell, Harry J. Gilbert, Gideon J. Davies
DOI: 10.1039/B301592K
Shape-persistent arylene ethynylene macrocycles: syntheses and supramolecular chemistry
Dahui Zhao, Jeffrey S. Moore
DOI: 10.1039/B207442G
Nonenzymatic peptide-based catalytic asymmetric phosphorylation of inositol derivatives
Bianca R. Sculimbrene, Adam J. Morgan, Scott J. Miller
DOI: 10.1039/B304015C
De novo design of non-hydrogen-bonded helical pseudopeptides composed of oxanipecotic acid oligomers
Myung-ryul Lee, Kwang-Yon Kim, Ung-In Cho, Doo Wan Boo, Injae Shin
DOI: 10.1039/B301382K
Strong optical limiting capability of a triosmium cluster bonded indium porphyrin complex [(TPP)InOs3(μ-H)2(CO)9(μ-η2-C5H4N)]
Xinhua Zhong, Yaoyu Feng, Say-Leong Ong, Jiangyong Hu, Wun-Jern Ng, Zheming Wang
DOI: 10.1039/B304349E
こちらもおすすめ
H-Leu-Ser-Lys-Leu-OH trifluoroacetate saltに適用される法規ガイドラインは何ですか?
CAS番号162559-45-7のH-Leu-Ser-Lys-Leu-OH trifluoroacetate saltは、GHS( Chemicals Clas...
Trimethyltin Chlorideの物理化学的性質は何ですか?
CAS番号1066-45-1のトリメチルチリドは、白色結晶性粉末で、分子量は297.77です。この化合物は水にわずかに溶けますが、酢酸、エタノール、ジエチルエー...
ニコール酸化物水和物の主な用途は何ですか?
ニコール酸化物水和物は、主に金属分離、研磨剤、酸化剤、染料製造の原料として利用されます。また、電気化学製品、触媒、分析化学の分野でも広く使用されています。
(2,3-二甲基-2H-吲唑-6-基)boronic acidを取り扱う際の実験室安全事項は何ですか?
(2,3-二甲基-2H-吲唑-6-基)boronic acidを取り扱う際は、PPE(防護服、ゴーグル、マスク、手袋)を使用する必要があります。ドラフトチャンバ...
4-ブロモ-1-メトキシ-2-(2-メトキシエトオキシ)ベンゼンは安全ですか?
4-ブロモ-1-メトキシ-2-(2-メトキシエトオキシ)ベンゼンは一般的に安全とは言えません。取扱いには注意が必要で、直接的な皮膚接触や吸入は避けてください。
4,4-双(5-甲基-2-苯并噁唑基)二苯乙烯はどの業界で使用されていますか?
4,4-双(5-甲基-2-苯并噁唑基)二苯乙烯は医薬業界、ポリマー業界、センサー業界、半導体業界で使用されています。特に、光触媒や蛍光材料として利用されています...
2,3,5,6-四氯-4-ピリジンスチオールを取り扱う際の実験室安全事項は何ですか?
2,3,5,6-四氯-4-ピリジンスチオールは非常に毒性があり、皮膚や粘膜に刺激を与える可能性があります。取り扱う際には、ゴーグル、ゴム手袋、防塵マスクを着用し...
TG 4-155はどのように合成されますか?
TG 4-155は、2-(2-メチル-1H-インドン-1-イル)エチルアミドと3,4,5-トリメトキシフェノールを反応させ、選択性的に合成できます。一般的には、...
エチルヒドロキシキニリン-6-カルボキシ酸は適用される法規ガイドラインは何ですか?
エチルヒドロキシキニリン-6-カルボキシ酸のCAS番号1261631-01-9は、GHS分類の第2クラスの腐食物質(皮膚に強い腐食性)に分類されます。また、EU...
掲載誌
Polymer Chemistry

Polymer Chemistry welcomes submissions in all areas of polymer science that have a strong focus on macromolecular chemistry. Manuscripts may cover a broad range of fields, yet no direct application focus is required.











![methyl 6-amino-1H-pyrrolo[2,3-b]pyridine-4-carboxylate structure methyl 6-amino-1H-pyrrolo[2,3-b]pyridine-4-carboxylate structure](https://static.chemtradehub.com/structs/119/1190315-60-6-9d9a.webp)

![3-(benzotriazol-1-yl)-N-[[2-[(3-bromophenyl)methoxy]phenyl]methylideneamino]propanamide structure 3-(benzotriazol-1-yl)-N-[[2-[(3-bromophenyl)methoxy]phenyl]methylideneamino]propanamide structure](https://static.chemtradehub.com/structs/559/5595-78-8-0a32.webp)
