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    • 3. 发明申请
    • METHODS FOR DETECTING AND/OR QUANTIFYING A CONCENTRATION OF SPECIFIC BACTERIAL MOLECULES USING BACTERIAL BIOSENSORS
    • 使用细菌生物传感器检测和/或定量特异性细菌分子的浓度的方法
    • US20090061464A1
    • 2009-03-05
    • US12176942
    • 2008-07-21
    • Kalle LEVONBin YuYanxiu Zhou
    • Kalle LEVONBin YuYanxiu Zhou
    • G01N33/554
    • C12Q1/00C07K9/00C07K14/32C07K17/00C12Q1/003G01N33/53G01N33/54353G01N33/5438G01N33/54393G01N33/552
    • A real-time method employing a portable peptide-containing potentiometric biosensor, can directly detect and/or quantify bacterial spores. Two peptides for specific recognition of B. subtilis and B. anthracis Sterne may be immobilized by a polysiloxane monolayer immobilization (PMI) technique. The sensors translate the biological recognition event into a potential change by detecting, for example, B. subtilis spores in a concentration range of 0.08-7.3×104 CFU/ml. The sensing method exhibited highly selective recognition properties towards Bacillus subtilis spores over other kinds of spores. The selectivity coefficients of the sensors for other kinds of spores are in the range of 0-1.0×10−5. The biosensor method not only has the specificity to distinguish Bacillus subtilis spores in a mixture of B. subtilis and B. thuringiensis (thur.) Kurstaki spores, but also can discriminate between live and dead B. subtilis spores. Furthermore, the sensing method can distinguish a Bacillus subtilis 1A700 from other B. subtilis strain. Assay time may be as low as about 5 minutes for a single test. Rapid identification of B. anthracis Sterne and B. anthracis ΔAmes was also provided.
    • 采用便携式含肽电位生物传感器的实时方法可以直接检测和/或定量细菌孢子。 用于特异性识别枯草芽孢杆菌和炭疽芽孢杆菌的两种肽可以通过聚硅氧烷单层固定(PMI)技术来固定。 传感器通过检测例如浓度范围为0.08-7.3×10 4 CFU / ml的枯草芽孢杆菌孢子将生物识别事件转化为潜在的变化。 该感测方法在其他种类的孢子上表现出对枯草芽孢杆菌孢子的高选择性识别性能。 其他类型孢子的传感器的选择性系数在0-1.0x10-5的范围内。 生物传感器方法不仅具有区分枯草芽孢杆菌和苏云金芽孢杆菌(Thur。)Kurstaki孢子的混合物中的枯草芽孢杆菌孢子的特异性,而且可以区分活枯枯病芽孢杆菌孢子和死枯病芽孢杆菌孢子。 此外,感测方法可以将枯草芽孢杆菌1A700与其他枯草芽孢杆菌菌株区分开。 单次测试的测定时间可能低至约5分钟。 炭疽杆菌和炭疽杆菌的快速鉴定也提供了DeltaAmes。
    • 4. 发明申请
    • Bacterial biosensors
    • 细菌生物传感器
    • US20050272105A1
    • 2005-12-08
    • US10888530
    • 2004-07-09
    • Kalle LevonBin YuYanxiu Zhou
    • Kalle LevonBin YuYanxiu Zhou
    • A61F13/15C12M1/34C12Q1/00G01N20060101G01N33/543G01N33/552G01N33/554G01N33/569
    • C12Q1/00C07K9/00C07K14/32C07K17/00C12Q1/003G01N33/53G01N33/54353G01N33/5438G01N33/54393G01N33/552
    • A real-time, portable peptide-containing potentiometric biosensor that can directly identify bacterial spores. Two peptides for specific recognition of B. subtilis and B. anthracis Sterne may be immobilized by a polysiloxane monolayer immobilization (PMI) technique. The sensors translate the biological recognition event into a potential change by detecting, for example, B. subtilis spores in a concentration range of 0.08-7.3×104 CFU/ml. The sensor exhibited highly selective recognition properties towards Bacillus subtilis spores over other kinds of spores. The selectivity coefficients of the sensors for other kinds of spores are in the range of 0-1.0×10−5. The biosensor system not only has the specificity to distinguish Bacillus subtilis spores in a mixture of B. subtilis and B. thuringiensis (thur.) Kurstaki spores, but also can discriminate between live and dead B. subtilis spores. Furthermore, the sensor can distinguish a Bacillus subtilis 1A700 from other B. subtilis strain. Assay time may be as low as about 5 minutes for a single test. Rapid identification of B. anthracis Sterne and B. anthracis ΔAmes was also provided.
    • 一种可直接鉴定细菌孢子的实时便携式含肽电位生物传感器。 用于特异性识别枯草芽孢杆菌和炭疽芽孢杆菌的两种肽可以通过聚硅氧烷单层固定(PMI)技术来固定。 传感器通过检测例如浓度范围为0.08-7.3×10 4 CFU / ml的枯草芽孢杆菌孢子将生物识别事件转化为潜在的变化。 传感器表现出对枯草芽孢杆菌孢子与其他种类孢子的高选择性识别性能。 用于其他种类孢子的传感器的选择性系数在0-1.0×10 -5的范围内。 生物传感器系统不仅具有将枯草芽孢杆菌和苏云金芽孢杆菌(thur。)Kurstaki孢子的混合物中的枯草芽孢杆菌孢子区分开的特异性,而且可以区分活枯枯病芽孢杆菌孢子和活枯草芽孢杆菌孢子。 此外,传感器可以将枯草芽孢杆菌1A700与其他枯草芽孢杆菌菌株区分开来。 单次测试的测定时间可能低至约5分钟。 炭疽杆菌和炭疽杆菌的快速鉴定也提供了DeltaAmes。
    • 7. 发明授权
    • Substrate imprinted universal sensors and sensors having nano-tunneling effect
    • 基板印制通用传感器和具有纳米隧道效应的传感器
    • US09052310B2
    • 2015-06-09
    • US12700927
    • 2010-02-05
    • Yanxiu Zhou
    • Yanxiu Zhou
    • G01N33/543B01J20/30
    • G01N33/54373B01J20/3057
    • A universal sensor fabrication approach, molecular substrate imprinting technique, which utilizes the interaction between molecular building blocks and the surface of a transducer to develop specific molecular recognition cavities has been established. Integration of molecular recognition cavities with the surface of a nanoscale transducer will result in a nano-tunneling effect that takes place which will provide a sensor or a device that exhibits new properties not already exhibited by either the molecular recognition cavities on a bulk transducer or the nanotransducer material. One of the new properties of this nano-tunneling effect is that a universal potentiometric molecular sensor can be fabricated and used to detect any compounds, whether they are ions or molecules, with enhanced selectivity, sensitivity, and stability when molecular recognition cavities or elements are integrated on the surface of a nanoscale transducer.
    • 已经建立了通用传感器制造方法,分子底物印记技术,其利用分子构建块和换能器表面之间的相互作用来开发特定的分子识别腔。 分子识别腔与纳米级换能器的表面的集成将导致发生纳米隧道效应,其将提供传感器或器件,该传感器或器件表现出新的性质,其尚未由体传感器上的分子识别腔或 纳米传感器材料。 这种纳米隧道效应的新特性之一是可以制造通用电位分子传感器,并用于检测任何化合物,无论它们是离子还是分子,当分子识别腔或元素为 集成在纳米尺度传感器的表面上。
    • 8. 发明申请
    • TWO-STEP MOLECULAR SURFACE IMPRINTING METHOD FOR MAKING A SENSOR
    • 用于制造传感器的两步分子表面印刷方法
    • US20080179191A1
    • 2008-07-31
    • US11668639
    • 2007-01-30
    • Yanxiu ZhouGeorge N. Maracas
    • Yanxiu ZhouGeorge N. Maracas
    • C25D5/00B05D3/10
    • G01N27/4035G01N27/333
    • A method is provided for detecting target molecules (60) using a surface-molecularly imprinted sensor (52) and more particularly for detecting hydroxyl containing molecules, heavy metal ions, or thiol- or dialkylamine containing molecules by integrating molecular recognition and sensor transduction. The method includes soaking a support surface (14) in a solution containing a ligand molecule with headgroups that could adsorb on the surface of a substrate, or monomer to create a monolayer, a monolayer of polymerized organosiloxane groups (16), or a conducting film on the support surface (14). Template molecules (18) are then added to the imprinting solution so as to be positioned within the sparsely formed film, wherein the template molecules (18) comprise hydroxyl containing molecules, heavy metal ions, or thiol and dialkylamine containing molecules which prevents the interaction between monomer/ligand molecules and template molecules (18). In this case, there is a competitive reaction between the hydroxyl group on the surface of substrate and hydroxyl in ethanol molecule with monomer, e.g. OTS. The template molecules (18) are removed to define cavities in the imprinted film (16).
    • 提供一种使用表面分子印迹传感器(52)检测目标分子(60)的方法,更具体地,通过整合分子识别和传感器转导来检测含羟基的分子,重金属离子或含巯基或二烷基胺的分子。 该方法包括将支撑表面(14)浸泡在含有配体分子的溶液中,所述溶液具有可吸附在基材表面上的头基,或单体以形成单层,单层聚合的有机硅氧烷基团(16)或导电膜 在支撑表面(14)上。 然后将模板分子(18)加入到印迹溶液中以便定位在稀疏形成的膜中,其中模板分子(18)包含含羟基的分子,重金属离子或含硫醇和二烷基胺的分子,其阻止了 单体/配体分子和模板分子(18)。 在这种情况下,底物表面的羟基与乙醇分子中的羟基与单体之间存在竞争性反应,例如。 OTS。 去除模板分子(18)以限定印刷膜(16)中的空腔。