fluorometric analysis

简明释义

荧光测定

英英释义

例句

1.In biomedical research, fluorometric analysis 荧光分析 is essential for measuring the concentration of biomolecules.

在生物医学研究中，荧光分析 fluorometric analysis对于测量生物分子的浓度至关重要。

2.The accuracy of fluorometric analysis 荧光分析 makes it a preferred method in clinical diagnostics.

由于其高准确性，荧光分析 fluorometric analysis成为临床诊断中的首选方法。

3.The laboratory used fluorometric analysis 荧光分析 to detect trace amounts of pollutants in water samples.

实验室使用荧光分析 fluorometric analysis来检测水样中微量污染物。

4.Using fluorometric analysis 荧光分析, scientists can monitor cellular processes in real-time.

科学家可以使用荧光分析 fluorometric analysis实时监测细胞过程。

5.Researchers employed fluorometric analysis 荧光分析 to quantify the levels of DNA in the samples.

研究人员采用荧光分析 fluorometric analysis来量化样本中的DNA水平。

作文

Fluorometric analysis is a powerful analytical technique widely used in various scientific fields, including biochemistry, environmental science, and clinical diagnostics. This method relies on the measurement of fluorescent light emitted by a sample when it is excited by a specific wavelength of light. The ability to detect and quantify substances at very low concentrations makes fluorometric analysis (荧光分析) an invaluable tool for researchers and professionals alike.One of the primary advantages of fluorometric analysis (荧光分析) is its sensitivity. Many compounds exhibit fluorescence, which allows for the detection of trace amounts of substances that would be difficult to measure using other techniques. For instance, in environmental monitoring, fluorometric analysis (荧光分析) can be employed to detect pollutants in water samples, ensuring compliance with safety regulations and protecting public health.In the field of biochemistry, fluorometric analysis (荧光分析) plays a crucial role in studying biomolecules. Researchers often use fluorescent dyes to label proteins, nucleic acids, or other cellular components. By measuring the intensity of fluorescence, scientists can gain insights into the concentration and behavior of these biomolecules within living cells. This application has been instrumental in advancing our understanding of cellular processes and disease mechanisms.Moreover, fluorometric analysis (荧光分析) is also commonly utilized in clinical diagnostics. For example, it is employed in assays to detect specific biomarkers associated with diseases. The high sensitivity of fluorometric analysis (荧光分析) enables early diagnosis, which is critical for effective treatment. In this context, the technique can be used to monitor disease progression or response to therapy, providing valuable information for healthcare providers.The procedure for conducting fluorometric analysis (荧光分析) typically involves several steps. First, the sample is prepared, which may include diluting the sample or adding fluorescent reagents. Next, the sample is exposed to light of a specific wavelength, causing the fluorescent compounds to emit light. Finally, the emitted light is measured using a fluorometer, which quantifies the intensity of fluorescence. This data can then be analyzed to determine the concentration of the target analyte.Despite its many benefits, fluorometric analysis (荧光分析) does have some limitations. For instance, the presence of interfering substances in a sample can affect the accuracy of the results. Therefore, careful consideration must be given to sample preparation and the choice of fluorescent probes. Additionally, not all compounds are fluorescent, which may limit the applicability of this technique in certain scenarios.In conclusion, fluorometric analysis (荧光分析) is an essential technique that has significantly contributed to advancements in various scientific disciplines. Its high sensitivity and ability to provide quantitative data make it a preferred method for detecting and analyzing a wide range of substances. As technology continues to evolve, it is likely that fluorometric analysis (荧光分析) will become even more prevalent, facilitating new discoveries and enhancing our understanding of complex biological systems. Researchers and clinicians must continue to refine their skills in this technique to maximize its potential and ensure accurate results in their respective fields.

荧光分析是一种强大的分析技术，广泛应用于生物化学、环境科学和临床诊断等多个科学领域。该方法依赖于测量样品在特定波长光照射下发出的荧光。检测和定量非常低浓度物质的能力使得荧光分析（fluorometric analysis）成为研究人员和专业人士不可或缺的工具。荧光分析（fluorometric analysis）的主要优势之一是其灵敏度。许多化合物表现出荧光，这允许检测微量物质，这在使用其他技术时将难以测量。例如，在环境监测中，荧光分析（fluorometric analysis）可用于检测水样中的污染物，确保符合安全规定并保护公众健康。在生物化学领域，荧光分析（fluorometric analysis）在研究生物分子方面发挥着至关重要的作用。研究人员常常使用荧光染料对蛋白质、核酸或其他细胞成分进行标记。通过测量荧光强度，科学家可以深入了解这些生物分子在活细胞内的浓度和行为。这一应用对推动我们对细胞过程和疾病机制的理解具有重要意义。此外，荧光分析（fluorometric analysis）也常用于临床诊断。例如，它被用于检测与疾病相关的特定生物标志物。荧光分析（fluorometric analysis）的高灵敏度能够实现早期诊断，这对有效治疗至关重要。在这个背景下，该技术可用于监测疾病进展或对治疗的反应，为医疗提供者提供有价值的信息。进行荧光分析（fluorometric analysis）的过程通常包括几个步骤。首先，准备样品，这可能包括稀释样品或添加荧光试剂。接下来，样品暴露在特定波长的光下，导致荧光化合物发光。最后，使用荧光仪测量发出的光，量化荧光强度。然后可以分析这些数据，以确定目标分析物的浓度。尽管有许多优点，荧光分析（fluorometric analysis）确实存在一些局限性。例如，样品中干扰物质的存在可能影响结果的准确性。因此，必须仔细考虑样品准备和荧光探针的选择。此外，并非所有化合物都是荧光的，这可能限制该技术在某些场景下的适用性。总之，荧光分析（fluorometric analysis）是一项重要的技术，对各个科学学科的进步做出了显著贡献。其高灵敏度和提供定量数据的能力使其成为检测和分析各种物质的首选方法。随着技术的不断发展，荧光分析（fluorometric analysis）可能会变得更加普遍，促进新的发现并增强我们对复杂生物系统的理解。研究人员和临床医生必须继续完善他们在这一技术上的技能，以最大化其潜力并确保在各自领域获得准确的结果。