DNA环介导恒温扩增技术快速检测霍乱弧菌

霍乱弧菌是一种重要的食源性致病菌,主要引起急性肠道传染病,其快速检测具有重要意义。根据霍乱弧菌的mdh管家基因序列,设计2对特异性检测引物,利用DNA环介导恒温扩增技术(Loop-mediated isothermal amplification,LAMP),经反应体系优化,成功建立了霍乱弧菌的LAMP快速检测方法。该方法最佳反应温度为65℃,60min完成检测,对培养菌的检测限为25CFU/mL,污染食品中霍乱弧菌的检测限为32CFU/g。对33株同种或近源细菌进行LAMP检测,仅霍乱弧菌得到阳性扩增。LAMP方法实践应用结果表明,对1057份虾、蟹、牡蛎、肉类、人腹泻物等样本进行检测,共检出85份阳性,与国际标准(ISO TS21872-1-2007)检测结果的符合率为100%。结果表明,本研究建立的霍乱弧菌LAMP检测方法特异性强、灵敏度高、操作简便,有利于霍乱弧菌疫情的监测。     

利用环介导恒温扩增法快速检测溶组织梭菌

目的:利用环介导恒温扩增技术(LAMP),设计快速检测溶组织梭菌的方法,研究其反应特性,以期能应用于气性坏疽溶组织梭菌感染的临床现场检验.方法:通过基因比对与引物设计,设计针对溶组织梭菌的环介导恒温扩增检测方法.然后检测该方法对溶组织梭菌及其他干扰菌的扩增情况,对其特异性进行评价.检测该方法对不同浓度溶组织梭菌的扩增情况,对其灵敏度进行评价.最后与全自动细菌培养法进行比较,评价其与常规检测方法的可比性.结果:本LAMP检测方法只针对溶组织梭菌有扩增,对其他15种菌不扩增,显示出良好的特异性.对溶组织梭菌的最低检测限为1× 101CFU/ml,显示其灵敏度较高.与全自动细菌培养法相比,有良好的可比性(P＜0.05),很高的灵敏度(92.6％)、特异性(98.1％)及准确度(97.3％).结论:本试验设计出了针对溶组织梭菌的LAMP检测方法,该LAMP检测方法具有良好的特异性较高的灵敏度,能够用于溶组织梭菌的临床现场检验.     

环介导恒温扩增技术快速检测溶藻弧菌

溶藻弧菌是中国南部水产养殖业中弧菌病的最主要病原菌,其快速检测具有重要意义.根据溶藻弧菌外膜蛋白OmpK基因序列,设计一套引物,通过条件优化.成功建立了针对致病性溶藻弧菌的环介导恒温扩增检测技术(loop-mediated isothennal amplification.LAMP).应用LAMP技术,在65℃温育1 h的条件下扩增溶藻弧菌基因组DNA.琼脂糖凝胶电泳得到特异性梯度条带.该研究建立的LAMP法特异性检出致病性溶藻弧菌,其检测下限比PCR法低一个数量级,相当于n(cell)=38/mL的菌液浓度,灵敏度更高.综合分析表明,LAMP技术是快速、简易、实地诊断溶藻弧菌的理想工具.     

环介导的恒温扩增技术及其在病毒性疾病诊断中的应用

环介导的恒温扩增（LAMP）是近年来新兴的一种快速DNA扩增技术,其基本原理在于利用4个特殊设计的引物和具有链置换活性的DNA聚合酶,在恒温条件下对靶序列进行扩增。LAMP技术具有特异性强、敏感性高、反应迅速、设备简单等特点,在人类病毒性疾病的诊断领域有着广泛的应用。     

环介导恒温扩增法快速检测短小芽孢杆菌

短小芽孢杆菌(Bacillus pumilus)是一种能引起食源性疾病的腐败菌,对其进行快速检测具有重要意义。针对短小芽孢杆菌木聚糖(xynA)基因,设计了4条特异性引物(两条内引物和两条外引物),通过条件优化,首次将一种新颖的核酸扩增技术——环介导恒温扩增技术应用于短小芽孢杆菌的快速检测。采用该技术,63℃温育1h的条件下扩增短小芽孢杆菌DNA,琼脂糖凝胶电泳得到特异性梯度条带。PCR和LAMP的检测灵敏度分别约为162和16.2拷贝每反应。结果表明,该方法检测短小芽孢杆菌特异性强、灵敏度高、操作简便、检测成本低,1h即可完成,有望发展成为快速检测短小芽孢杆菌的有效手段。     

环介导恒温扩增法快速检测海产品中的副溶血弧菌

副溶血弧菌广泛分布于海水或海产品中,人类摄入或接触污染的水源和食物易引起感染。近年来,有关致病性弧菌引起腹泻的报道逐渐增多,但GB标准的细菌学诊断方法检测周期长达1周左右,而且操作较为复杂,难以满足控制疾病暴发和传播的需要,就这一现状,建立了一套不仅快速、准确,而且操作简便、不依赖昂贵仪器的检测方法,应用于海产品中副溶血弧菌快速检测。采用环介导恒温扩增方法(LAMP),针对副溶血弧菌的gyrB基因设计特异引物,进行恒温扩增。使用该方法最低检出限达到101CFU/mL,灵敏度可以达到0.1pg副溶血弧菌基因组DNA,为海产品中副溶血弧菌的检测提供了一个新的辅助方法。     

DNA环介导的恒温扩增法在快速鉴定病原微生物中的应用

DNA环介导的恒温扩增(LAMP)反应,是分子生物学领域中的一个新概念,它可以在恒温(60～65℃)条件下,30～60 min内将只有几个拷贝的靶核酸扩增到109水平。该方法的一大特色是,可以通过反应副产物——白色焦磷酸镁沉淀的产生与否判断靶基因的存在。因此,对于病原微生物的鉴定具有高效率、高特异性、高敏感性等特点。LAMP方法在食品安全检测、流行性病毒检测、临床诊断,以及水产养殖等领域的应用及研究已有文献报道。表明,该方法已具有成功应用的现实性,为快速基因检测提供了一种新的技术途径;比PCR方法更具推广性,可望作为常规检测工具。     

基于颜色判定的环介导恒温扩增法快速检测副溶血性弧菌

利用DNA环介导恒温核酸扩增法（LAMP）针对副溶血性弧菌特异基因tlh基因设计4条引物,通过引物特异性识别tlh基因上的6个独立区域来快速检测副溶血性弧菌.LAMP反应的过程中会产生白色沉淀焦磷酸镁,故可以通过监测浊度来判定反应结果.实时浊度仪监测反应结果表明,LAMP反应在60～65℃恒温条件下50min内完成;如果在反应前添加羟基萘酚兰（HNB）,蓝色的阳性结果很明显区别于紫色阴性结果;LAMP方法的最低检出限为9.74pg/μL,PCR方法最低检出限为97.4pg/μL,LAMP方法检测灵敏度是PCR方法检测灵敏度的10倍,且具有良好的特异性.LAMP方法用于快速检测副溶血性弧菌具有检测过程简单、实验装置简便、反应结果肉眼可辨别、灵敏度高和特异性强的特点,所以LAMP方法检测副溶血性弧菌特别适合用于现场和基层检疫及医疗单位的快速诊断.     

水产品中创伤弧菌DNA环介导恒温扩增快速检测方法的建立及初步应用

创伤弧菌是一种重要的食源性致病菌,主要存在于河口和海洋环境中,严重危害水产养殖业的发展和人类健康。建立快速、准确、易操作的检测方法对防控创伤弧菌的传染,保障水产养殖业发展和增强食品安全意义重大。基于创伤弧菌vvHA基因,利用一种新型的核酸扩增技术-环介导恒温扩增(loop-mediated isothermal amplification,LAMP),建立了创伤弧菌LAMP快速检测方法。对11种共46株细菌进行扩增,仅创伤弧菌为LAMP阳性结果,说明LAMP方法具有高度特异性。灵敏度试验结果表明,对创伤弧菌纯培养菌的检测灵敏度为15CFU/ml,对污染食品中创伤弧菌的检测灵敏度为24CFU/g。此法40~60min内即可完成检测,检验检疫实践证明:LAMP方法操作简便、特异性强、灵敏度高且成本低廉,具有良好的应用前景。     

环介导恒温扩增技术在呼吸道感染常见细菌临床检测中的应用评价

【背景】传统的细菌培养为下呼吸道感染诊断的金标准,但其检验周期长且敏感性低。环介导恒温扩增(loop-mediated isothermal amplification,LAMP)技术方法简单、检测快速,可应用于临床呼吸道感染常见细菌的快速检测。【目的】评估环介导恒温扩增技术对呼吸道感染常见7种细菌的检测能力。【方法】设计呼吸道感染常见的7种病原菌肺炎克雷伯菌(Klebsiella pneumoniae,KP)、鲍曼不动杆菌(Acinetobacter baumannii,AB)、金黄色葡萄球菌(Staphylococcus aureus,SA)、铜绿假单胞菌(Pseudomonas aeruginosa,PA)、肺炎链球菌(Streptococcus pneumoniae,SP)、卡他莫拉菌(Moraxella catarrhalis,MC)和流感嗜血杆菌(Haemophilus influenzae,HI)的环介导恒温扩增特异性引物,建立检测7种病原菌的LAMP方法。通过梯度稀释的方法检测敏感性,交叉反应实验检测特异性。回顾性分析2019年11月–2021年3月北京大学人民医院的2...     

Detection of periodontal pathogen Porphyromonas gingivalis by loop-mediated isothermal amplification method

A method for nucleic acid amplification, loop-mediated isothermal amplification (LAMP) was employed to develop a rapid and simple detection system for periodontal pathogen, Porphyromonas gingivalis. A set of six primers was designed by targeting the 16S ribosomal RNA gene. By the detection system, target DNA was amplified and visualized on agarose gel within 30 min under isothermal condition at 64 degrees C with a detection limit of 20 cells of P. gingivalis. Without gel electrophoresis, the LAMP amplicon was directly visualized in the reaction tube by addition of SYBR Green I for a naked-eye inspection. The LAMP reaction was also assessed by white turbidity of magnesium pyrophosphate (a by-product of LAMP) in the tube. Detection limits of these naked-eye inspections were 20 cells and 200 cells, respectively. Although false-positive DNA amplification was observed from more than 10(7) cells of Porphyromonas endodontalis, no amplification was observed in other five related oral pathogens. Further, quantitative detection of P. gingivalis was accomplished by a real-time monitoring of the LAMP reaction using SYBR Green I with linearity over a range of 10(2)-10(6) cells. The real-time LAMP was then applied to clinical samples of dental plaque and demonstrated almost identical results to the conventional real-time PCR with an advantage of rapidity. These findings indicate the potential usefulness of LAMP for detecting and quantifying P. gingivalis, especially in its rapidity and simplicity.     

Monitoring the progression of loop-mediated isothermal amplification using conductivity

Loop-mediated isothermal amplification (LAMP) yields a large amount of DNA, as well as magnesium pyrophosphate precipitate, causing a decrease in ionic strength that can be measured with a conductivity meter. There is a clear relationship between the conductivity of the LAMP mixture solution and the duration of biochemical reaction. Moreover, there is also a clear relationship between the change in conductivity and the amount of initial template DNA over the range of 0.08 to 3.2 ng. These results demonstrate the feasibility not only for detecting the LAMP product qualitatively but also for real-time monitoring the biochemical reaction progression quantitatively using conductivity measurements.     

Detection of phytoplasma by loop-mediated isothermal amplification of DNA (LAMP)

Napier stunt phytoplasma (16SrXI and 16SrIII) in eastern Africa is a serious threat to the expansion of Napier grass (Pennisetum purpureum) farming in the region, where it is widely cultivated as fodder in zero grazing livestock systems. The grass has high potential for bio-fuel production, and has been adopted by farmers as a countermeasure to cereal stem borer Lepidoptera, since it attracts and traps the insect. Diagnosis of stunt phytoplasma have been largely by nested polymerase chain reaction (nPCR) targeting the 16S rRNA gene. However, the method is laborious, costly and technically demanding. This investigation has developed a simpler but effective phytoplasma diagnostic tool, called; loop-mediated isothermal amplification of DNA (LAMP). The assay was tested on 8 symptomatic and 8 asymptomatic plants, while its detection limit was compared to nested PCR using samples serially diluted from 3 ng/μl to 0.38 pg/μl. Molecular typing of LAMP products was determined by BsrI restriction digestion and Southern blot analysis. The assay sensitivity, positive and negative predictive values were estimated, while the specificity was tested on 11 phytoplasma groups. LAMP was specific to 5 phytoplasma groups: 16SrVI, X, XI and XVI. BsrI restriction digestion produced two predicted fragments, and there was specific binding of probe DNA to the LAMP amplicons in Southern blot analysis. The assay sensitivity was 100%, while the positive and negative predictive values were 63 and 100% respectively. LAMP was 20-fold more sensitive than nested PCR. This study validates LAMP for routine diagnosis of Napier stunt and other closely related phytoplasmas.     

环介导等温扩增技术对解脲脲原体的临床检测

目的建立并优化环介导等温扩增(LAMP)技术对解脲脲原体(U.urealyticum)的检测,并应用于临床样本分析。方法针对U.urealyticum的urease基因设计LAMP引物;研究LAMP的最适温度、最佳检测时间及灵敏度和特异度;与传统PCR检测进行方法学比对。结果 LAMP技术检测U.urealyticum的最适温度和最佳时间分别是61℃和60 min,并且具有良好灵敏度和特异度,较普通PCR检测的灵敏度高出1 000倍。临床样本检测中,PCR和LAMP技术达到的灵敏度分别为25.00%和87.50%。两种方法的特异度均为100.00%。结论 LAMP与PCR相比在基层检测和大规模筛查方面有显著的优势和巨大的利用价值。     

环介导等温扩增技术改进的研究进展

环介导等温扩增法(LAMP)是近年发展起来的新型核酸检测技术,因其检测特异性好、灵敏度高、时间短、无需热循环设备而在病原体检测中得到广泛应用。基于该技术进行的改造和改良也层出不穷,本文从该技术的方法改造、缩短反应时间和简化模板预处理、多重扩增产物分析、防止假阳性污染四个方面对近几年LAMP技术的发展进行综述,为今后以该技术平台为基础的创新和应用提供理论依据。     

Detection of Botrytis cinerea by loop-mediated isothermal amplification

Aims: To develop a sensitive, rapid and simple method for detection of Botrytis cinerea based on loop‐mediated isothermal amplification (LAMP) that would be suitable for use outside a conventional laboratory setting. Methods and Results: A LAMP assay was designed based on the intergenic spacer of the B. cinerea nuclear ribosomal DNA (rDNA). The resulting assay was characterized in terms of sensitivity and specificity using DNA extracted from cultures. The assay consistently amplified 65 pg B. cinerea DNA. No cross‐reactivity was observed with a range of other fungal pathogens, with the exception of the closely related species Botrytis pelargonii. Use of a novel real‐time LAMP platform (the OptiGene Genie I) allowed detection of B. cinerea in infected rose petals, with amplification occurring in <15 min. Conclusions: The LAMP assay that was developed is suitable for rapid detection of B. cinerea in infected plant material. Significance and Impact of the Study: The LAMP method combines the sensitivity and specificity of nucleic acid‐based methods with simplified equipment and a reduced reaction time. These features make the method potentially suitable for on‐site use, where the results of testing could help to inform decisions regarding the storage and processing of commodities affected by B. cinerea, such as cut flowers, fruit and vegetables.     

Detection of fish nocardiosis by loop-mediated isothermal amplification

AIMS: Loop-mediated isothermal amplification (LAMP) is a novel method that amplifies DNA with high specificity and rapidity under isothermal conditions. In this study, using the LAMP method, a protocol for detecting Nocardia seriolae which is a causative agent of fish nocardiosis, was designed. METHODS AND RESULTS: A set of four primers, two inner and two outer, were designed based on the sequence of the 16S-23S ribosomal RNA internal transcribed spacer region of N. seriolae. Time and temperature conditions for detection of N. seriolae were optimized for 60 min at 65 degrees C. Other fish pathogen was not amplified by this LAMP system. The detection of N. seriola using LAMP was found to be more sensitive than that by polymerase chain reaction. CONCLUSIONS: LAMP is a highly sensitive and rapid diagnostic procedure for detection of N. seriolae. SIGNIFICANCE AND IMPACT OF THE STUDY: LAMP is a useful diagnostic method for fish nocardiosis.     

Tolerance of loop-mediated isothermal amplification to a culture medium and biological substances

To simplify the molecular detection of micro-organisms, we evaluated the tolerance of loop-mediated isothermal amplification (LAMP) to a culture medium and some biological substances. The sensitivity of LAMP was less affected by the various components of the clinical samples than was polymerase chain reaction (PCR); therefore, DNA purification from samples could be omitted.