- 产品描述
药物含违禁品检测试纸(胶体金法)
广州健仑生物科技有限公司
主营品牌:美国US、美国Alfa、美国NovaBios、美国Cortez、国产创仑等等。
主要用途:筛查违禁品滥用残留、麻醉类药物残留、兴奋类药物残留等等。
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独立包装:BZO-BAR-COC--THC -MET--OPI-OXY-MDMA-PCP- AMP-XTC-MTD 或联检
药物含违禁品检测试纸(胶体金法)
A rapid, one step test for the qualitative detection of Amphetamines in human urine. For healthcare professionals including professionals at point of care sites For professional in vitro diagnostic use only.
【检验方法】
在进行检测前必须先完整阅读使用说明书,使用前将本品和尿样恢复至室温(20℃~30℃)。
- 撕开铝箔袋,取出试剂盒,应在1小时内尽快使用。
- 将试剂盒置于干净平坦的台面上,用塑料吸管垂直滴加3滴无空气泡的尿样(约100µL)于加样孔(S)中。
- 等待紫红色条带的出现,3~5分钟时直接观察结果,10分钟后判定无效。
【参考值(参考范围)】
本品zui低检出量指标参照美国药物滥用和精神健康服务管理局(SAMHSA)确定的阳性检测临界浓度的标准进行制定。能检测出尼古丁含量不低于300ng/mL的样本。
【检验结果的解释】
阳性(+):仅在控制区(C)出现一条紫红色条带,在检测区(T)无紫红色条带出现。阳性结果表明尿液中的尼古丁浓度在阈值(300ng/mL)以上。
阴性(-):出现两条紫红色条带。一条位于检测区(T),另一条位于控制区(C)。阴性结果表明尿液中的尼古丁浓度在阈值(300ng/mL)以下。
无效:控制区(C)未出现紫红色条带。表明操作不当或试剂盒已失效。在此情况下,应再次仔细阅读说明书,并用新的试剂盒重新测试。如果问题仍然存在,应立即停止使用此批号产品,并与当地供应商。
注意:检测区(T)紫红色条带可呈现颜色深浅的现象。但是,在规定的观察时间内,不论该色带颜色深浅,即使只有非常弱的色带也应判定为阴性结果。
美国NOVABIOS多联检测杯简介:
产品名称 | 规格 | 检测违禁品类型 |
违禁品十联检测杯 | 25T/盒 | MET.AMP.MTD.THC.BAR.TCA.COC.BZO.PCP.OPI |
违禁品十三联检测杯 | 25T/盒 | AMP.BAR.BZO.COC.MET.MOR.MTD.PCP.PPX.TCA.THC.XTC.WADU |
违禁品十二联检测杯 | 25T/盒 | BZO.BAR.COC.THC.MET.OPI.OXY.MDMA.PCP.AMP.BUP.MTD
|
美国NOVABIOS单卡产品简介:
产品名称 | 英文缩写 | 检测阀值 |
吗啡检测试剂盒 | MOP(OPI) | 300ng/ml |
mamp检测试剂盒 | MAMP(MET) | 1000ng/ml |
K检测试剂盒 | KET | 1000ng/ml |
Ecstasy检测试剂盒 | MDMA | 500ng/ml |
cocaine检测试剂盒 | COC | 300ng/ml |
hemp检测试剂盒 | THC | 50ng/ml |
Amphetamine检测试剂盒 | AMP | 1000ng/ml |
Benzene two nitrogen Zhuo检测试剂盒 | BZO | 300ng/ml |
巴比妥检测试剂盒 | BAR | 300ng/ml |
Methadone检测试剂盒 | MTD | 300ng/ml |
药物含违禁品检测试纸(胶体金法)
一是相对于抗生素,重组噬菌体具有细菌度特异性,不会影响正细菌菌群;二是所有重组噬菌体都是基于相同的遗传框架,有利于获得监管部门的批准。预计该项研究成果将进一步加速噬菌体生物学的研究,也有助于开发新技术定向“编辑”细菌菌群。在治疗败血症的时候,医生通细菌会使用广谱抗生素治疗。但是,在某些情况下,一些细菌对抗生素具有耐药性,而细菌的抗生素耐药性分析是一个耗时耗力的过程,对于很多患者来说,如果等到耐药性分析结果后再进行治疗就显得太晚了。日前,德国弗劳恩霍夫应用研究促进协会的科学家们开发出一个新的技术,可以在短短九小时内得到细菌耐药性分析结果。
患者的血液中毒,也被称为败血症,需要医护人员迅速给出诊断和治疗。有的医生会立刻开始使用广谱抗生素,但抗生素并不总是有理想的效果。如果细菌具有广谱耐药性(如携带编码新德里金属-β-内酰胺酶-1(NDM-1)基因的细菌),对临床细菌用的大多数抗生素具有耐药性,那么抗生素就可能会失效。
在实验室鉴定引起败血症的细菌原菌,并对它们的潜在的抗生素耐药性进行调查,通细菌需要60-100个小时。而细菌人却等不起,大多数情况下败血症患者会在48小时左右死亡。如果能在更短的时间内完成感染细菌原菌的耐药性分析,医生根据分析结果对细菌人进行有针对性的抗生素治疗,其治疗效果将更有效,如此将挽救更多细菌人的生命。在德国,每年约有6万人因为败血症而死亡。
现在,德国科学家开发了一种新的检测方法,让人们在短得多的时间内完成细菌原菌耐药性分析成为了现实,利用这种新方法,可以在9小时内就得到结果。
从本质上讲,这个检测技术的核心是,细菌在不同抗生素环境下的生长,可以被光学系统精确地观察和记录到。研究人员们开发了一个小型化的系统,这个系统具有特殊的光学设计。检测的*步是标记引起败血症的细菌原菌,使他们暴露在激光环境下。这使得研究人员能够评估血液中存在的细菌原体数量。然后将细菌原菌从血液中分离出来并进入单独的培养区。
尿液试纸、唾液试纸、尼古丁检测卡、烟碱检测卡、违违禁品三联检测卡、违禁品五联检测卡、违禁品十联检测卡、药筛试剂、违禁品滥用检测试纸、违禁品快速检测试剂盒
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【公司名称】 广州健仑生物科技有限公司
【 市场部 】 杨永汉
【】
【腾讯 】
【公司地址】 广州市清华科技园健新基地番禺石楼镇健启路63号二期2幢101-103室
First, relative to antibiotics, the recombinant bacteriophage has bacteriocin specificity and does not affect the positive bacterium flora. Second, all recombinant bacteriophages are based on the same genetic framework, which is conducive to regulatory approval. The research is expected to further accelerate the study of bacteriophage biology and to help develop new technologies to target "edit" bacterial flora. In the treatment of sepsis, the doctor through the bacteria will use broad-spectrum antibiotics. However, in some cases some bacteria are resistant to antibiotics, and antibiotic resistance analysis of bacteria is a time-consuming process that for many patients will wait until the result of a drug resistance analysis Treatment is too late. Recently, scientists from the Fraunhofer-Institute-of-Applied Research Association in Germany have developed a new technology that will give results of bacterial resistance analysis in as little as nine hours.
Patients with blood poisoning, also known as sepsis, require medical staff to quickly give diagnosis and treatment. Some doctors immediay start using broad-spectrum antibiotics, but antibiotics do not always have the desired effect. If the bacterium has broad-spectrum resistance (such as carrying a gene encoding the New Delhi metallo-β-lactamase-1 (NDM-1) gene) and is resistant to most antibiotics used in clinical bacteria, the antibiotic may Failure.
Bacterial pathogens causing sepsis were identified in the laboratory and their potential antibiotic resistance was investigated, with bacteria requiring 60-100 hours. The bacteria can not wait, in most cases, sepsis patients will die in about 48 hours. If antibiotic resistance of infected bacterial pathogens can be completed in a shorter period of time, the doctor will conduct targeted antibiotic treatment on the bacteria according to the analysis result, and the treatment effect will be more effective, which will save more human lives of bacteria . In Germany, about 60,000 people die each year because of sepsis.
Now, German scientists have developed a new assay that allows people to complete bacterial pathogenicity analysis in a much shorter period of time. With this new method, results can be obtained within 9 hours.
Essentially, the heart of this detection technique is the growth of bacteria in different antibiotic environments that can be accuray observed and recorded by optical systems. Researchers have developed a miniaturized system that has a special optical design. The first step in testing is to mark the bacteria that cause sepsis and expose them to the laser. This allows researchers to assess the amount of bacterial pathogens present in the blood. Bacterial germs are then separated from the blood and into separate culture zones.