Mn-doped ZnS quantum dots/methyl violet nanohybrids for room temperature phosphorescence sensing of DNA

Mn-doped ZnS quantum dots/methyl violet nanohybrids were explored to develop a novel room temperature phosphorescence (RTP) sensor for the detection of DNA. Methyl violet (MV) as the electron acceptors was adsorbed on the surface of the quantum dots (QDs) to quench the RTP of the Mn-doped ZnS QDs through an electron-transfer process under excitation. The addition of DNA recovered the RTP signal of the Mn-doped ZnS QDs due to the binding of MV with DNA and the removal of MV from the surface of the Mn-doped Z...     

量子点室温磷光探针检测生物体液中的头孢哌酮钠舒巴坦钠

以水相合成的3-巯基丙酸包覆的Mn掺杂ZnS量子点(MPA-Mn/ZnS QDs)作为室温磷光探针, 基于头孢哌酮钠舒巴坦钠(CPZ-SBT)作为一种电子受体, 可通过电子转移有效猝灭Mn/ZnS QDs的室温磷光效应, 构建了一种测定痕量CPZ-SBT的方法. 当CPZ-SBT浓度为0.7~84 μg/L时, 其与MPA-Mn/ZnS QDs的磷光强度之间呈良好线性关系, 相关系数为0.99, 该方法的检出限为0.14 μg/L.     

ZnS:Mn/ZnS量子点在DNA定量分析中的应用

以巯基乙酸为稳定剂,采用成核掺杂的方法在水溶液中一步制备得到具有核壳结构的ZnS:Mn/ZnS量子点.研究了荧光、室温磷光产生的机理.基于DNA对量子点发光的增强效应,以ZnS:Mn/ZnS量子点作为标记探针建立了测定DNA的荧光、室温磷光的分析方法.考察了量子点浓度、EDC/NHS用量和反应时间等条件对DNA测定的影...     

A Convenient “Turn On-off” Phosphorescent Nanosensor for Detection of Biotin Based on Quantum Dots/CTAB

A switchable room-temperature phosphorescence(RTP) nanosensor based on an MPA-capped Mn-doped ZnS QDs/CTAB composite system(MPA=3-mercaptopropionic acid; CTAB=cetyltrimethyl ammonium bromide; QDs=quantum dots) was established for the detection of biotin. The phosphorescence intensity of QDs/CTAB could be regularly quenched with the increase of biotin. Under optimal conditions, this method yielded two linear ranges of 2-20 μg/L and 20-140 μg/L with respective correlation coefficients of 0.993 and 0.990, as well as a detection limit of 0.93 μg/L. Therefore, the analytical potential of the proposed nanosensor was evaluated by detecting biotin in urine and biotin tablets. This approach yielded satisfactory results because of the effective elimination of background fluorescence and light scattering from the sample matrix. This approach provides a practical method for biotin detection.     

基于Mn掺杂ZnS量子点室温磷光法检测盐酸巴马汀

本文以3-巯基丙酸(3-Mercaptopropionic Acid,MPA)为稳定剂,采用水相合成法制备了Mn掺杂ZnS量子点(Mn∶ZnS QDs),基于Mn∶ZnS QDs的室温磷光性质,盐酸巴马汀(Palmatine Hydrochloride,PaH)可与Mn∶ZnS QDs发生静电作用,使得Mn∶ZnS QDs发生室温磷光猝灭效应,从而发展了一种高效、快速检测人体体液中痕量PaH的新方法。实验结果表明,当PaH的浓度在0.75~30μmol/L范围时,其浓度与室温磷光猝灭强度(ΔIRTP)呈良好的线性关系,相关系数为0.996,检出限为0.35μmol/L,加标回收率为94.0%~103.3%。     

基于室温磷光量子点/硼酸基联吡啶盐纳米复合材料检测果糖

以Mn掺杂的ZnS(Mn-ZnS)室温磷光(RTP)量子点的磷光为信号,以2-溴甲基苯硼酸与4,4ˊ-联吡啶为原料合成的硼酸基联吡啶盐(BBV)为受体,带负电的量子点与带正电BBV通过静电作用形成Mn-ZnS/BBV纳米复合材料,Mn-ZnS量子点磷光猝灭,加入果糖,BBV与果糖形成阴离子硼酸酯,降低了对量子点猝灭效率,RTP恢复.考察了时间、pH值对Mn掺杂的ZnS QDs/BBV纳米复合材料磷光强度的影响,在最优条件下,此传感器检测果糖的线性范围为0.05~1.00 mmol/L,检出限为0.01 mmol/L,相关系数r为0.99.本磷光分析法简便快速、灵敏度高,有望应用于食品、医药行业中果糖含量的检测分析.     

ZnS∶Mn量子点表面印迹杂化膜的研制及其在荧光识别4-硝基苯酚中的应用

采用工艺简单的水相合成法制备ZnS∶Mn量子点,并在量子点表面进行硅烷化处理,包覆一层分子印迹聚合物.将量子点与壳聚糖混合,在石英玻片上沉积,制备杂化膜,并用于4-硝基苯酚的快速测定,线性范围为1.0～8.0 μmol/L;检出限为41 nmol/L.此膜表现出较好的灵敏度和良好的选择性.此杂化膜具有良好的稳定性、重复使用性和可逆再生性,在无水乙醇中浸泡即可实现再生.本方法用于环境样品中4-对硝基苯酚的测定,回收率为95.5％～103.0％.     

基于Mn掺杂ZnS量子点磷光内滤效应检测β-葡萄糖醛酸酶

高效荧光内滤分析的关键是使猝灭剂的吸收峰与荧光团的激发峰或发射峰最大限度地重叠.本研究将Mn掺杂ZnS量子点(Mn-ZnS QDs)作为内滤体系的荧光体,4-硝基苯-β-D-葡糖苷酸(PNPG)作为吸收体,实现了β-葡萄糖醛酸酶(GUS)的特异性检测.PNPG的吸收光谱与Mn-ZnS QDs的激发光谱大幅重叠,能够高效猝灭Mn-ZnS QDs的磷光.由于Mn-ZnS QDs具有较大的斯托克斯位移(约300 nm),其激发光谱和发射光谱与GUS的酶解产物PNP的吸收光谱几乎无重叠,因而实现了GUS的磷光Turn-on检测.此外,Mn-ZnS QDs具有优异的室温磷光性质,可以避开生物组织荧光背景,从而可有效应用于生物样品分析.据此建立了一种基于内滤效应的GUS磷光探针,实现了对大肠杆菌的测定.本方法在最优的实验条件下对10~300 U/L的GUS有线性响应,检出限为7 U/L,且本策略相对于紫外-可见光谱法有很好的抗基底干扰能力.     

Amiloride-modulated phosphorescence turn-off/on method for the detection of abasic site-containing dsRNA based on uridine triphosphate-capped Mn-doped ZnS quantum dots

RNA plays a crucial role in biochemical processes. RNAs with abasic sites (AP-RNA), as one of RNA lesions, will cause serious negative consequences. Efficient and sensitive detection of AP-RNA deserves but does not receive enough attention. Water-soluble uridine triphosphate (UTP)-capped Mn-doped ZnS quantum dots (QDs), which have excellent room-temperature phosphorescence (RTP) properties, were prepared by wet-chemical method. The UTP on the surface of QDs could form a precipitation complex with amiloride (AMI) to quench the RTP. Meanwhile, abasic double-stranded RNA (AP-dsRNA) with a high affinity to AMI could dissociate AMI from the surface of UTP-QDs, resulting in RTP recovery. In this process, a highly sensitive and selective RTP-detection system for AP-dsRNA was constructed with AMI as the modulation factor and UTP-QDs as the luminescence matrix. RTP was turned off and on for the determination of AP-dsRNA, and the interference of background fluorescence and scattered light was effectively avoided during complex formation and aggregation. Steric hindrance of the conformation of AP-dsRNA provided efficient selectivity. The detection limit for AP-dsRNA was 0.86 nM, the relative standard deviation was 2.1%, and the recovery of biological samples with AP-dsRNA addition ranged from 95% to 103% at optimal conditions. The system is expected to provide new methods for environmental monitoring, early disease screening, and evaluation of gene editing efficiency.     

基于Mn掺杂ZnS量子点的室温磷光传感应用的研究进展

与一般有机染料分子相比,半导体材料量子点具有优异的光学性能,在多个领域得到了广泛的应用.量子点具有窄而对称且可调的发射波长、宽激发强吸收、抗光漂白能力强以及水溶性好等诸多优势,引起了研究者广泛关注.为了增加量子点的斯托克斯位移从而很好地避免量子点的自猝灭现象,引入掺杂物是一种很有效的方式.掺杂量子点不仅保留了量子点原有的优点,而且还赋予量子点额外的优异性能.如Mn掺杂ZnS量子点生物相容性好,不含Cd和Hg等有害元素,而且Mn2+的加入使其具有优异的室温磷光特性.磷光检测能很好地避开生物背景荧光的干扰,使得Mn掺杂ZnS量子点能够广泛应用于磷光生物分析.本文综述了Mn掺杂ZnS量子点在室温磷光分析中的研究进展,着重介绍了几种具有启发意义的设计策略,包括其发光机理以及应用于离子、分子以及生物大分子等的检测.     

采用一锅法制备量子点/琼脂纳米复合凝胶

以天然高分子琼脂为稳定剂,采用简单便捷的一锅法制备Mn掺杂ZnS量子点/琼脂纳米复合凝胶,琼脂不仅作为制备量子点的稳定剂,同时也是纳米复合凝胶的主要成分。对该纳米复合凝胶中量子点的化学结构和尺寸大小进行了表征,并对纳米复合凝胶的荧光性能和凝胶性能进行了研究。实验结果表明,制备得到的纳米复合凝胶均一稳定,在302 nm紫外光下呈现十分明显的橙红色荧光。在该纳米复合凝胶的透射电子显微镜（TEM）表征中可以观察到大小比较均一、粒径为3 nm左右的纳米粒子,光谱分析结果进一步证实纳米复合凝胶中存在Mn掺杂ZnS量子点。该纳米复合凝胶不仅具有良好的荧光性能,还具有温度刺激响应性可逆溶胶-凝胶转变性能,同时具有较高的溶胶转变温度和较好的温度稳定性。利用这些性能特点,可以方便地制备纳米复合凝胶小球。此外,该纳米复合凝胶还可以被潜在应用于金属离子的荧光检测分析领域。     

Superoxide dismutase mimetic ability of Mn-doped ZnS QDs

The Mn-doped ZnS QDs were synthesized by a facile and one-pot method and possess intrinsic superoxide dismutase-like activity.     

In situ formation of p–n junction: A novel principle for photoelectrochemical sensor and its application for mercury(II) ion detection

The discovery and development of photoelectrochemical sensors with novel principles are of great significance to realize sensitive and low-cost detection. In this paper, a new photoelectrochemial sensor based on the in situ formation of p–n junction was designed and used for the accurate determination of mercury(II) ions. Cysteine-capped ZnS quantum dots (QDs) was assembled on the surface of indium tin oxide (ITO) electrode based on the electrostatic interaction between Poly(diallyldimethylammonium chloride) (PDDA) and Cys-capped ZnS QDs. The in situ formation of HgS, a p-type semiconductor, on the surface of ZnS facilitated the charge carrier transport and promoted electron-hole separation, triggered an obviously enhanced anodic photocurrent of Cys-capped ZnS QDs. The formation of p–n junction was confirmed by P–N conductive type discriminator measurements and current–voltage (I–V) curves. The photoelectrochemical method was used for the sensing of trace mercuric (II) ions with a linear concentration of 0.01 to 10.0 µM and a detection limit of 4.6 × 10⁻⁹ mol/L. It is expected that the present study can serve as a foundation to the application of p–n heterojunction to photoelectrochemical sensors and it might be easily extended to more exciting sensing systems by photoelectrochemistry.     

硫鸟嘌呤修饰的Mn:ZnS QDs磷光探针检测铂(Ⅲ)

通过水相合成法制备了硫鸟嘌呤(TG)修饰的锰掺杂硫化锌量子点(TG-Mn:ZnS QDs)。加入Pt⁴⁺后,Pt⁴⁺会与硫鸟嘌呤上的氮原子结合形成N-Pt⁴⁺配位结构附着在TG-Mn:ZnS QDs的表面,随着Pt⁴⁺浓度的增加,TG-Mn:ZnS QDs-Pt⁴⁺体系发生电子转移而导致磷光逐渐被猝灭,基于此构建了检测Pt⁴⁺的磷光探针。实验中考察了p H、时间对Pt⁴⁺猝灭TG-Mn:ZnS QDs磷光强度的影响。在最佳实验条件下,Pt⁴⁺浓度在0.06~2.4μg/mL范围内与TG-Mn:ZnS QDs的磷光强度呈良好的线性关系y=0.0884x+0.2319,R²=0.991,方法检出限(3σ/n)为1.3μg/mL。该磷光探针适用于实际样品中Pt⁴⁺含量的测定。     

Synthesis of bovine serum albumin imprinted Mn:ZnS quantum dots

A novel bovine serum albumin（BSA） imprinted Mn-doped ZnS quantum dots（Mn:ZnS QDs） is firstly reported.The molecular imprinted polymer（MIP） functionalized Mn:ZnS QDs（Mn:ZnS@SiO₂@MIP） include the preparation of Mn:ZnS QDs,the coating of silica on the surface of Mn:ZnS QDs,and the functional polymerization by sol-gel reaction using 3-aminophenylboronic acid as the functional and cross-linking monomer in the presence of BSA（Mn:ZnS@SiO₂@MIP-BSA）,and then the elution of the imprinted BSA on the surface of Mn:ZnS@SiO₂ QDs.The results showed that the phosphorescence of Mn:ZnS@SiO₂@MIP is stronger quenched by BSA than that of non-imprinted one（Mn:ZnS@SiO₂@NIP）,indicating that the selectivity of the imprinted Mn:ZnS quantum dots toward BSA is superior to that of non-imprinted one.     

分子印迹Mn掺杂ZnS量子点磷光法检测烟酸转化液中的6-羟基烟酸

以6-羟基烟酸(6-HNA)为模板,采用分子印迹溶胶-凝胶法合成了具有良好光学性质的印迹Mn掺杂Zn S量子点磷光传感器(MIP-QDs)。红外光谱(FT-IR)和扫描电镜(SEM)测试表明,印迹聚合物成功接枝在纳米传感器表面。吸附试验显示,MIP-QDs对6-HNA的亲和性与选择性显著高于其结构类似物阔马酸和烟酸,具备作为检测探针的潜力。在最优条件下,基于6-HNA可选择性猝灭MIP-QDs磷光而建立了灵敏、简便的检测微量6-HNA的光学新方法。当6-HNA浓度在3.4~67.0μmol/L范围内,MIP-QDs的磷光猝灭率P_0/P随浓度变化的关系符合Stern-Volmer方程(r~2=0.996 5),检出限为1.03μmol/L。实际样品测定显示,6-HNA的回收率为91.0%~103.9%,相对标准偏差不超过4.5%,检测结果与HPLC法相一致(P0.05),方法具有良好的准确性和可行性。     

3-Aminopropyltriethoxysilane-functionalized manganese doped ZnS quantum dots for room-temperature phosphorescence sensing ultratrace 2,4,6-trinitrotoluene in aqueous solution

New strategies for silica coating of inorganic nanoparticles became a research hotspot for enhancing the mechanical stability of colloidal particles and protecting colloidal particles against oxidation and agglomeration, and so on. In this paper, 3-aminopropyltriethoxysilane (APTES)-functionalized Mn doped (AF MnD) ZnS QDs was prepared to be firsyly through the use of silane coupling agents to form an active layer of silica, then sol-gel reaction of TEOS co-deposited with APTES on the surface of resultant active layer of silica. The emitted long lifetime room-temperature phosphorescence (RTP) of the resultant nanomaterials allows an appropriate delay time so that any fluorescent emission and scattering light can be easily avoided. The APTES anchored on the layer of silica can bind 2,4,6-trinitrotoluene (TNT) species to form TNT anion through acid-base pairing interaction, the TNT anion species may increase the charge-transfer pathways from the nanocrystals to nitroaromatic analytes, therefore further enhance the quenching efficiency of RTP. Moreover, APTES as capped reagents can enlarge the spectral sensitivity and enhance RTP response of nanocrystals to the electron-deficient nitroaromatic and nitrophenol species. Meanwhile, AF MnD ZnS QDs also exhibited a highly selective response toward TNT analyte through significant color change and quenching of ⁴T₁ to ⁶A₁ transition emission. This AF MnD ZnS QDs based sensor showed a very good linearity in the range of 0.05-1.8 μM with detection limit down to 50 nM (quenching percentage of phosphorescence intensity of 8%) and RSD of 3.5% (n = 5). The reported QDs-based chemosensors here open up a promising prospect for the sensitive and convenient sensing of TNT explosive.     

胆碱氧化酶功能化室温磷光量子点的制备及其对氯化胆碱的定量检测

环境友好型纳米生物传感器能够提高传统生物分子传感器的检测性能，在实际应用中具有重要的应用价值。本研究以胆碱氧化酶（ChOx）为模板，在室温（25 ℃）下通过矿化作用制备了一种ChOx功能化的室温磷光（RTP）量子点（QDs）（ChOx RTP QDs）纳米生物传感器，并利用ChOx与氯化胆碱的特异性酶-底物反应和光诱导的电子转移（PIET）实现了对氯化胆碱（Cho）的RTP定量检测。该纳米生物传感器对氯化胆碱检测的线性范围为0.05~20 mmol/L，检出限为0.02 mmol/L。该方法基于QDs的RTP性质，可以有效地避免生物样品背景荧光的干扰，且无需复杂的样品前处理过程，因此该方法较适合于生物样品中氯化胆碱的定量检测。     

Ascorbic Acid Induced Enhancement of Room Temperature Phosphorescence of Sodium Tripolyphosphate‐Capped Mn‐Doped ZnS Quantum Dots: Mechanism and Bioprobe Applications

Although quantum dot (QD)‐based room temperature phosphorescence (RTP) probes are promising for practical applications in complex matrixes such as environmental, food and biological samples, current QD‐based‐RTP probes are not only quite limited but also exclusively based on the RTP quenching mechanism. Here we report an ascorbic acid (AA) induced phosphorescence enhancement of sodium tripolyphosphate‐capped Mn‐doped ZnS QDs, and its application for turn‐on RTP detection. The chelating ability allows AA to extract the Mn and Zn from the surface of the QDs and to generate more holes which are subsequently trapped by Mn²⁺, while the reducing property permits AA to reduce Mn³⁺ to Mn²⁺ in the excited state, thereby enhancing the excitation and orange emission of the QDs. The enhanced RTP intensity of the QDs increases linearly with the concentration of AA in the range of 0.05–0.8 μM . Thus, a QD‐based RTP probe for AA is developed. The proposed QD‐based turn‐on RTP probe avoids tedious sample pretreatment, and offers good sensitivity and selectivity for AA in the presence of the main relevant metal ions and other molecules in biological fluids. The limit of detection (3s) of the developed method is 9 nM AA, and the relative standard deviation is 4.8 % for 11 replicate detections of 0.1 μM AA. The developed method is successfully applied to the analysis of real samples of human urine and plasma for AA with quantitative recoveries from 96 to 105 %.     

(CdSe)ZnS quantum dots and organophosphorus hydrolase bioconjugate as biosensors for detection of paraoxon

In this paper, we first report a novel biosensor for the detection of paraoxon based on (CdSe)ZnS core-shell quantum dots (QDs) and an organophosphorus hydrolase (OPH) bioconjugate. The OPH was coupled to (CdSe)ZnS core-shell QDs through electrostatic interaction between negatively charged QDs surfaces and the positively charged protein side chain and ending groups (-NH2). Circular dichroism (CD) spectroscopy showed no significant change in the secondary structure of OPH after the bioconjugation, which indicates that the activity of OPH was preserved. Detectable secondary structure changes were observed by CD spectroscopy when the OPH/QDs bioconjugate was exposed to organophosphorus compounds such as paraoxon. Photoluminescence (PL) spectroscopic study showed that the PL intensity of the OPH/QDs bioconjugate was quenched in the presence of paraoxon. The overall quenching percentage as a function of paraoxon concentration matched very well with the Michaelis-Menten equation. This result indicated that the quenching of PL intensity was caused by the conformational change in the enzyme, which is confirmed by CD measurements. The detection limit of paraoxon concentration using OPH/QDs bioconjugate was about 10(-8) M. Although increasing the OPH molar ratio in the bioconjugates will slightly increase the sensitivity of biosensor, no further increase of sensitivity was achieved when the molar ratio of OPH to QDs was greater than 20 because the surface of QDs was saturated by OPH. These properties make the OPH/QDs bioconjugate a promising biosensor for the detection of organophosphorus compounds.