Bead-Based Optical Immunoassay Using Quantum-Dot Labeling and Immunocomplex Dissociation for Detection of Escherichia coli O157:H7

An immunoassay for Escherichia coli O157:H7 using quantum-dot (QD) labeling and subsequent release of the QD labels from immunocomplexes has been developed. The assay principle is that anti-E. coli O157:H7 conjugated immunomagnetic beads are used to capture E. coli O157:H7; this is followed by the binding of QD labeled antibodies to form sandwich immunocomplexes (Bead-Cell-QD); a dissociation buffer then elutes QDs from immunocomplexes by denaturing antibody or lysing cell; the fluorescence signal of the eluted QDs is measured to quantify E. coli O157:H7. This proposed approach avoids the interference of bead autofluorescence in signal transduction and, thus, enhances the detection resolution, while keeping the fast magnetic separation and sandwich binding of two selective antibodies for high specificity.     

Avidin: a natural bridge for quantum dot-antibody conjugates

We describe the preparation and characterization of bioinorganic conjugates in which luminescent semiconductor CdSe-ZnS core-shell nanocrystal quantum dots (QDs) were coupled to antibodies through the use of an avidin bridge adsorbed to the nanocrystal surface via electrostatic self-assembly. Avidin, a highly positively charged protein, was found to adsorb tightly to QDs modified with dihydrolipoic acid, which gives their surface a homogeneous negative charge. QD conjugation to biotinylated antibodies subsequently is readily achieved. Fluoroimmunoassays utilizing these antibody conjugated QDs were successful in the detection of protein toxins (staphylococcal enterotoxin B, cholera toxin). QD-antibody conjugates formed in such a facile manner permit their use as a common immuno reagent, and in the development of multianalyte detection.     

基于二氧化硅荧光纳米颗粒与核酸染料SYBRGreenⅠ的双色显微成像技术用于E.coliO157:H7的检测

将免疫荧光纳米标记技术与激光共聚焦显微成像方法相结合,发展了一种基于二氧化硅荧光纳米颗粒和核酸染料SYBR Green Ⅰ的双色显微成像技术用于大肠杆菌O157:H7的检测.采用联吡啶钌(RuBpy)二氧化硅荧光纳米颗粒对羊抗大肠杆菌O157:H7抗体进行修饰,基于抗体-抗原相互作用实现了其对目标大肠杆菌O157:H7...     

Influence of quantum dot's quantum yield to chemiluminescent resonance energy transfer

The resonance energy transfer between chemiluminescence donor (luminol-H₂O₂ system) and quantum dots (QDs, emission at 593 nm) acceptors (CRET) was investigated. The resonance energy transfer efficiencies were compared while the oil soluble QDs, water soluble QDs (modified with thioglycolate) and QD-HRP conjugates were used as acceptor. The fluorescence of QD can be observed in the three cases, indicating that the CRET occurs while QD acceptor in different status was used. The highest CRET efficiency (10.7%) was obtained in the case of oil soluble QDs, and the lowest CRET efficiency (2.7%) was observed in the QD-HRP conjugates case. This result is coincident with the quantum yields of the acceptors (18.3% and 0.4%). The same result was observed in another similar set of experiment, in which the amphiphilic polymer modified QDs (emission at 675 nm) were used. It suggests that the quantum yield of the QD in different status is the crucial factor to the CRET efficiency. Furthermore, the multiplexed CRET between luminol donor and three different sizes QD acceptors was observed simultaneously. This work will offer useful support for improving the CRET studies based on quantum dots.     

Detection of melanoma using antibody-conjugated quantum dots in a coculture model for high-throughput screening system

We proposed an effective strategy for evaluating the targeting specificity of an antibody-conjugated quantum dot (QD) nanoprobe in a coculture system mimicking an in vivo-like tumor microenvironment in which cancer cells grow with normal cells. Analysis of the images was performed with automated confocal microscopy. We have employed a melanoma-melanocyte coculture model to assess the specific binding of QDs conjugated with melanoma antibodies. Conjugation of antibodies to the QD significantly improved the melanoma specificity, while unconjugated antibody alone suffered from non-specific binding to melanocytes. Concentration-dependent binding and competitive inhibition studies with QD-antibody conjugates reproducibly proved the specificity to melanoma cells against melanocytes. The specificity and targeting efficiency of nanoprobes evaluated in a simple coculture model may provide a reasonable assessment for the in vitro diagnosis of early stage melanoma development before in vivo studies. Further, a rapid and sensitive cancer cell detection system demonstrated herein may allow for the development of high-throughput screening platforms for early cancer diagnosis and anti-cancer therapeutics.     

Simple conjugation and purification of quantum dot-antibody complexes using a thermally responsive elastin-protein L scaffold as immunofluoresecent agents

Fluorescent quantum dots (QDs), because of their tunable spectral properties, are ideal for simultaneous multiplexed detection in an antibody array format. Despite these advantages, their widespread usage is limited by the costly and tedious conjugation and separation protocol. Herein, we report a simple platform for the direct conjugation and separation of highly luminescent CdSe-ZnS QD-antibody complexes using a genetically engineered polyhistidine tagged elastin-protein L fusion (His-ELP-PL). The principle of immunoassay-ready conjugates was to take advantage of the direct conjugation of QDs via metal coordination with the His tag, the unique temperature-responsive property of ELP, and the high affinity of the antibody-binding protein L domain toward IgGs. Simple separation of the QD- His-ELP-PL-IgG complex was achieved by thermally triggered precipitation without any interference on the QD functionality. The utility of the biofunctionalized OD probes was demonstranted in an antibody array for the detection of carcinoembryonic antigen.     

Gold nanoparticle-based homogeneous fluorescent aptasensor for multiplex detection

We developed a homogeneous fluorescence assay for multiplex detection based on the target induced conformational change of DNA aptamers. DNA aptamers were immobilized on quantum dots (QDs), and QDs conjugated ssDNA was adsorbed on the surface of gold nanoparticles (AuNPs) by electrostatic interaction between uncoiled ssDNA and the AuNPs. Subsequently the fluorescence of QDs was effectively quenched by the AuNPs due to fluorescence resonance energy transfer (FRET) of QDs to AuNPs. In the presence of targets, the QDs conjugated aptamers were detached from AuNPs by target induced conformational change of aptamers, consequently the fluorescence of the QDs was recovered proportional to the target concentration. In this study, three different QD/aptamer conjugates were used for multiplex detection of mercury ions, adenosine and potassium ions. In a control experiment, all of the three targets were simultaneously detected with high selectivity.     

Detection of DNA Hybridization via Fluorescence Intensity Variations of ZnSe-DNA Quantum Dot Biosensors

ZnSe quantum dots (QDs) that were capped with 11-mercaptoundecanoic acid (MUA) and conjugated to amino-modified ssDNA molecules exhibited variations in fluorescence emission intensity upon hybridization with complementary ssDNA in solution, a phenomenon that can be exploited for rapid detection of free ssDNA sequences. Conjugation of MUA-capped ZnSe QDs to amino-modified ssDNA molecules resulted in increased fluorescence emission intensity and stability at room temperature. Increasing the length of the ssDNA, that was conjugated to the QDs, resulted in increased fluorescence emission intensity up to a length of about 50 nucleotide bases, beyond which the peak emission intensity reached a plateau. Hybridization of QD-ssDNA conjugates with complementary ssDNA, either in free form or bound to QDs from the same population, resulted in additional fluorescence emission intensity amplification. A small red shift was observed when three-dimensional QD-dsDNA-QD structures were formed. The QD-ssDNA sensors with single ssDNA molecule per QD were developed and used for rapid quantitative detection of fully or partially complementary free ssDNA sequences in aqueous solution. Partial hybridization of the QD-ssDNA sensors with short ssDNA targets resulted in smaller QD emission intensity amplification, when compared to full hybridization. A QD-ssDNA sensor containing a sequence corresponding to the hemoglobin beta gene was used to detect and discriminate between free ssDNA targets consisting of a complementary ssDNA sequence and targets containing a single-base mutation that can cause sickle-cell anemia. Such QD-based biosensors can form the basis for rapid separation-free assays that can be used to detect target biomolecules in solution.     

Development and characterization of a magnetic bead-quantum dot nanoparticles based assay capable of Escherichia coli O157:H7 quantification

The development and characterization of a magnetic bead (MB)-quantum dot (QD) nanoparticles based assay capable of quantifying pathogenic bacteria is presented here. The MB-QD assay operates by having a capturing probe DNA selectively linked to the signaling probe DNA via the target genomic DNA (gDNA) during DNA hybridization. The signaling probe DNA is labeled with fluorescent QD₅₆₅ which serves as a reporter. The capturing probe DNA is conjugated simultaneously to a MB and another QD₆₅₅, which serve as a carrier and an internal standard, respectively. Successfully captured target gDNA is separated using a magnetic field and is quantified via a spectrofluorometer. The use of QDs (i.e., QD₅₆₅/QD₆₅₅) as both a fluorescence label and an internal standard increased the sensitivity of the assay. The passivation effect and the molar ratio between QD and DNA were optimized. The MB-QD assay demonstrated a detection limit of 890 zeptomolar (i.e., 10⁻²¹ mol L⁻¹) concentration for the linear single stranded DNA (ssDNA). It also demonstrated a detection limit of 87 gene copies for double stranded DNA (dsDNA) eaeA gene extracted from pure Escherichia coli (E. coli) O157:H7 culture. Its corresponding dynamic range, sensitivity, and selectivity were also presented. Finally, the bacterial gDNA of E. coli O157:H7 was used to highlight the MB-QD assay's ability to detect below the minimum infective dose (i.e., 100 organisms) of E. coli O157:H7 in water environment.     

Characterization and separation of semiconductor quantum dots and their conjugates by capillary electrophoresis

Semiconductor quantum dots (QDs) are very important luminescent nanomaterials with a wide range of potential applications. Currently, QDs as labeling probes are broadly used in bioassays, including immunoassay, DNA hybridization, and bioimaging, due to their excellent physical and chemical properties, such as broad excitation spectra, narrow and size‐dependent emission profiles, long fluorescence life time, and good photostability. The characterization of QDs and their conjugates is crucial for their wide bioapplications. CE has become a powerful tool for the separation and characterization of QDs and their conjugates. In this review, some CE separation models of QDs are first introduced, mainly including CZE, CGE, MEKC, and ITP. And then, some key applications, such as the measurements of size, surface charge, and concentration of QDs and the characterization of QDs conjugates (e.g. QD–protein, QD–DNA, QD–small molecule), are also described. Finally, future perspectives are discussed.     

Bovine serum albumin-directed synthesis of biocompatible CdSe quantum dots and bacteria labeling

A simple method was developed for preparing CdSe quantum dots (QDs) using a common protein (bovine serum albumin (BSA)) to sequester QD precursors (Cd(2+)) in situ. Fluorescence (FL) and absorption spectra showed that the chelating time between BSA and Cd(2+), the molar ratio of BSA/Cd(2+), temperature, and pH are the crucial factors for the quality of QDs. The average QD particle size was estimated to be about 5 nm, determined by high-resolution transmission electron microscopy. With FL spectra, Fourier transform infrared spectra, and thermogravimetric analysis, an interesting mechanism was discussed for the formation of the BSA-CdSe QDs. The results indicate that there might be conjugated bonds between CdSe QDs and -OH, -NH, and -SH groups in BSA. In addition, fluorescence imaging suggests that the QDs we designed can successfully label Escherichia coli cells, which gives us a great opportunity to develop biocompatible tools to label bacteria cells.     

Quantum dot enabled detection of Escherichia coli using a cell-phone

We report a cell-phone based Escherichia coli (E. coli) detection platform for screening of liquid samples. In this compact and cost-effective design attached to a cell-phone, we utilize anti-E. coli O157:H7 antibody functionalized glass capillaries as solid substrates to perform a quantum dot based sandwich assay for specific detection of E. coli O157:H7 in liquid samples. Using battery-powered inexpensive light-emitting-diodes (LEDs) we excite/pump these labelled E. coli particles captured on the capillary surface, where the emission from the quantum dots is then imaged using the cell-phone camera unit through an additional lens that is inserted between the capillary and the cell-phone. By quantifying the fluorescent light emission from each capillary tube, the concentration of E. coli in the sample is determined. We experimentally confirmed the detection limit of this cell-phone based fluorescent imaging and sensing platform as ～5 to 10 cfu mL(-1) in buffer solution. We also tested the specificity of this E. coli detection platform by spiking samples with different species (e.g., Salmonella) to confirm that non-specific binding/detection is negligible. We further demonstrated the proof-of-concept of our approach in a complex food matrix, e.g., fat-free milk, where a similar detection limit of ～5 to 10 cfu mL(-1) was achieved despite challenges associated with the density of proteins that exist in milk. Our results reveal the promising potential of this cell-phone enabled field-portable and cost-effective E. coli detection platform for e.g., screening of water and food samples even in resource limited environments. The presented platform can also be applicable to other pathogens of interest through the use of different antibodies.     

Capillary electrophoresis immunoassays with conjugated quantum dots

Water-soluble CdTe quantum dots (QDs) and their conjugates with antibodies and antigenes were prepared by optimized procedures for applications in CE immunoassays. The QD size of 3.5 nm, excitation spectrum in the range of 300-500 nm, the maximum wavelength of the emission spectrum at 610 nm, quantum yield of 0.25 and luminescence lifetimes in the range of 3.6-43 ns were determined. The 0.1 M solution of TRIS/TAPS (pH 8.3) was found to be the optimum buffer for the separation of the antiovalbumin-ovalbumin immunocomplex from the free conjugates of QDs.     

Multi-analyte homogenous immunoassay based on quenching of quantum dots by functionalized graphene

We propose a homogenous multi-analyte immunoassay based on the quenching of quantum dot (QD) fluorescence by means of graphene. Two QDs with emission maxima at 636 and 607 nm were bound to antibodies selective for mouse or chicken immunoglobulins, respectively, and graphene functionalized with carboxylic moieties was employed to covalently link the respective antigen. The antibody-antigen interaction led graphene close enough to QDs to quench the QD fluorescence by resonance energy transfer. The addition of free antigens that competed with those linked to graphene acted as a “turn-on” effect on QD fluorescence. Fluorescence emitted by the two QDs could be recorded simultaneously since the QDs emitted light at different wavelengths while being excited at the same wavelength and proved to be linearly correlated with free antigen concentration. The developed assay allows measuring both antigens over 2–3 orders of magnitude and showed estimated limits of detection in the nanomolar range. This approach is thus a promising universal strategy to develop homogenous immunoassays for diverse antigens (cells, proteins, low-molecular-mass analytes) in a multi-analyte configuration.     

Rapid and ultrasensitive E. coli O157:H7 quantitation by combination of ligandmagnetic nanoparticles enrichment with fluorescent nanoparticles based two-color flow cytometry

A novel, fast and sensitive determination strategy for E. coli O157:H7 has been developed by combination of ligandmagnetic nanoparticles (LMNPs) enrichment with a fluorescent silica nanoparticles (FSiNPs) based two-color flow cytometry assay (LMNPs@FSiNPs-FCM). E. coli O157:H7 was first captured and enriched through the lectin concanavalin A (Con A) favored strong adhesion of E. coli O157:H7 to the mannose-conjugated magnetic nanoparticles. The enriched E. coli O157:H7 was further specially labeled with goat anti-E. coli O157:H7 antibody modified RuBpy-doped FSiNPs, and then stained with a nucleic acid dye SYBR Green I (SYBR-I). After dual-labeling with FSiNPs and SYBR-I, the enriched E. coli O157:H7 was determined using multiparameter FCM analysis. With this method, the detection sensitivity was greatly improved due to the LMNPs enrichment and the signal amplification of the FSiNPs labelling method. Furthermore, the false positives caused by aggregates of FSiNPs conjugates and nonspecific binding of FSiNPs to background debris could be significantly decreased. This assay allowed the detection of E. coli O157:H7 in PB buffer at levels as low as 7 cells mL(-1). The total assay time including E. coli O157:H7 sample enrichment and detection was less than 4 h. An artificially contaminated bottled mineral water sample with a concentration of 6 cells mL(-1) can be detected by this method. It is believed that the proposed method will find wide applications in biomedical fields demanding higher sensitive bacterial identification.     

Characterization of quantum dot bioconjugates by capillary electrophoresis with laser-induced fluorescent detection

In this paper, we present a universal, highly efficient and sensitive method for the characterization of quantum dot (QD) bioconjugates based on capillary electrophoresis with laser-induced fluorescent (LIF) detection. We first prepared CdTe QDs in aqueous phase by a chemical route with mercaptopropionic acid as a ligand, and then were coupled to certain proteins using bifunctional linkage reagent or electrostatic attraction. The QD bioconjugates were characterized by capillary electrophoresis with LIF detection. We found that QD bioconjugates were efficiently separated with free QDs by the optimization of buffer pH. Furthermore, we found that ultrafiltration was an effective and simple approach to purify QD conjugates with bovine serum albumin (BSA). Due to their broad absorption spectra and size dependent emission wavelength tunability, QDs can be excited to emit different colour fluorescence using a single wavelength laser source, and therefore, we believe that CE with LIF detection will become a universal and efficient tool for the characterization of QD bioconjugates.     

Homogenous rapid detection of nucleic acids using two-color quantum dots

We report a homogenous method for rapid and sensitive detection of nucleic acids using two-color quantum dots (QDs) based on single-molecule coincidence detection. The streptavidin-coated quantum dots functioned as both a nano-scaffold and as a fluorescence pair for coincidence detection. Two biotinylated oligonucleotide probes were used to recognize and detect specific complementary target DNA through a sandwich hybridization reaction. The DNA hybrids were first caught and assembled on the surface of 605 nm-emitting QDs (605QDs) through specific streptavidin-biotin binding. The 525 nm-emitting QDs (525QDs) were then added to bind the other end of DNA hybrids. The coincidence signals were observed only when the presence of target DNA led to the formation of 605QD/DNA hybrid/525QD complexes. In comparison with a conventional QD-based assay, this assay provided high detection efficiency and short analysis time due to its high hybridization efficiency resulting from the high diffusion coefficient and no limitation of temperature treatment. This QD-based single-molecule coincidence detection offers a simple, rapid and ultra sensitive method for genomic DNA analysis in a homogenous format.     

基于甘露糖功能化的水凝胶用于E.coli O157: H7的检测

利用伴刀豆球蛋白A(Con A)的多价结合能力, 结合水凝胶技术与核酸染色技术发展了一种基于甘露糖功能化的水凝胶检测大肠杆菌(E.coli)O157: H7的方法. 以过硫酸铵(APS)为催化剂, 四甲基乙二胺(TEMED)为加速剂, 用丙烯酰胺(AAm)、N,N-二甲基双丙烯酰胺和N-丙烯酰氧琥珀酰亚胺(NAS)合成水凝胶, 通过氨基化甘露糖与NAS发生交联反应, 制备了甘露糖功能化的水凝胶. 当甘露糖功能化的水凝胶加入与Con A共孵育后的菌悬液中时, 由于Con A既能与甘露糖特异性结合, 又能与E.coli O157: H7表面的O-抗原发生免疫反应而紧密连接, 使目标菌被捕获到水凝胶表面, 采用核酸染料SYBR Green Ⅰ对捕获细菌进行染色, 实现了对E.coli O157: H7的核酸标记, 最后通过活体荧光成像系统对水凝胶进行荧光成像, 从而实现对待测样品的检测. 研究结果表明, 该方法可应用于缓冲液体系和混合细菌样品中E.coli O157: H7的特异性检测, 且整个检测步骤包括样品预处理可在2 h内完成. 该方法成本低、易操作, 且具有较好的灵敏度, 可检出3.7×10¹ Cells/mL的目标细菌样品.     

一种实用的基于化学发光和磁性纳米颗粒的E.coli O157:H7免疫鉴定方法

化学发光磁酶免疫已经被应用于检测病原体,但是由于针对相应病原体的抗体筛选和修饰等的步骤耗时费力,不适于对多种病原体进行筛查.制备了兔抗大肠杆菌(E.coli)O157:H7的免疫磁性纳米颗粒,富集病原菌后与鼠抗E.coli O157:H7的单克隆抗体形成双抗夹心,采用碱性磷酸酶标记的马抗鼠IgG与单抗结合,加入碱性磷酸酶的化学发光底物试剂3-(2'-螺旋金刚烷)-4-甲氧基-4-(3'-羟基)苯-1,2-二氧杂环丁烷磷酸检测化学发光.实验研究了底物缓冲液、碱性磷酸酶浓度对化学发光强度的影响,比较了NaBH4和甘氨酸对免疫磁珠剩余活性醛基的封闭效果以及本方法检测E.coli O157:H7的特异性和敏感性.结果表明,碱性磷酸酶与底物在c缓冲液中反应的化学发光强度最高,碱性磷酸酶浓度决定了化学发光的强度和持续时间,NaBH4对活性醛基的封闭效果优于甘氨酸,以D群宋内氏志贺氏菌、B群福氏志贺氏菌、鼠伤寒沙门氏菌、金黄色葡萄球菌和霍乱弧菌及E.coli Top10f'为对照的比较实验显示,该检测方法具有良好的特异性,以1mL的菌液为检测体积时对E.coli O157:H7的检测灵敏度为103cell/mL,整个方法的检测时间约为3h.该方法适用于对多样本进行筛查.     

Generation of singlet oxygen via the composites of water-soluble thiol-capped CdTe quantum dots-sulfonated aluminum phthalocyanines

Singlet oxygen (1O2), one of the reactive oxygen species, plays an important role in many biomedical applications. The various compounds including the phthalocyanines, quantum dots (QDs) and QD complex, which may have potential to produce 1O2, thus received more and more attentions in recent years. By means of the direct detection of near-infrared 1270 nm, we found that the water-soluble thiol-capped CdTe QDs can photoproduce 1O2 in deuterated water with a low quantum yield (QY) of 1%. When sulfonated aluminum phthalocyanines (AlSPc's) were connected to these QDs, forming water-soluble QD-Pc composites, the 1O2 QY of the composites increased to 15% under the excitation of 532 nm, while little 1O2 production can be found for AlSPc alone at the same excitation because of the poor absorption of AlSPc in this region. The results of indirect measurements of 1O2, obtained from the photodegradation of the 1O2 chemical trap anthracene-9,10-diyl-bis-methylmalonate (ADMA), confirmed 1O2 yields in both QD and QD-Pc composite solutions. The QD-Pc composites have the advantage of extending the excitation region to 400-600 nm with remarkably enhanced extinction coefficients as compared with that of AlSPc. Therefore QD-Pc composites can fully utilize visible region light excitation to effectively produce 1O2, which may facilitate the applications of QD-Pc composites in broad areas.