densitometric

简明释义

英[/ˌdɛn.sɪˈtɒm.ɪ.trɪk/]美[/ˌdɛn.sɪˈtɒm.ɪ.trɪk/]

密度计的

英英释义

单词用法

同义词

反义词

例句

1.It works continuously in a logistic concept with feedback to the sample preparation, the instrumentation Settings, the densitometric measurements, and the diagnostic interpretation.

它通过反馈信息这种符合逻辑概念的方式，在标本的制作、仪器的设置、光密度分析的测量、诊断结果的判读中连续发挥着作用。

2.It works continuously in a logistic concept with feedback to the sample preparation, the instrumentation Settings, the densitometric measurements, and the diagnostic interpretation.

它通过反馈信息这种符合逻辑概念的方式，在标本的制作、仪器的设置、光密度分析的测量、诊断结果的判读中连续发挥着作用。

3.This paper has reported recent advancement of TLC-densitometric analysis in bio- logical science.

本文综述了薄层扫描法近年来在生命科学中的应用进展。

4.The study focused on densitometric 密度测定的 measurements of bone density in patients.

该研究集中于患者骨密度的密度测定的测量。

5.The densitometric 密度测定的 analysis revealed significant variations in the material's properties.

该密度测定的分析揭示了材料特性的重要变化。

6.In photography, densitometric 密度测定的 analysis helps in understanding the exposure levels of images.

在摄影中，密度测定的分析有助于理解图像的曝光水平。

7.Using densitometric 密度测定的 techniques, researchers were able to quantify the levels of pollutants in the water.

通过使用密度测定的技术，研究人员能够量化水中的污染物水平。

8.The laboratory used a densitometric 密度测定的 method to analyze the sample's concentration.

实验室使用了一种密度测定的方法来分析样品的浓度。

作文

In the realm of scientific research and various fields of study, the term densitometric (密度测量的) plays a crucial role in understanding materials and their properties. Densitometry is a technique that measures the density of substances, which can provide valuable insights into their composition and behavior. The importance of densitometric analysis can be seen across multiple disciplines, including chemistry, biology, and even medical imaging.For instance, in chemistry, densitometric methods are often employed to determine the concentration of solutions. By measuring the density of a solution, scientists can infer how much solute is present. This is particularly useful in titration experiments where precise concentrations are essential for accurate results. A densitometric approach allows chemists to quickly assess the outcomes of their experiments and make necessary adjustments to achieve the desired concentrations.Similarly, in the field of biology, densitometric techniques are utilized to analyze the density of cells or biological samples. For example, researchers may use densitometric measurements to evaluate cell proliferation or apoptosis by quantifying the density of cells in cultures. This information can be critical in drug development, where understanding how cells respond to treatments can lead to breakthroughs in therapies for various diseases.Moreover, densitometric analysis is also significant in the medical field, particularly in imaging technologies. Techniques such as X-ray imaging and computed tomography (CT) scans rely on densitometric principles to create detailed images of the body's internal structures. The density of different tissues affects how they absorb or transmit X-rays, allowing radiologists to discern between various types of tissues and identify potential abnormalities. This application of densitometric analysis not only aids in diagnosis but also assists in planning treatment strategies.In addition to these applications, densitometric methods have found their way into quality control processes in manufacturing. Industries such as food and beverage, pharmaceuticals, and materials science employ densitometric techniques to ensure products meet specific density standards. For example, the density of a liquid product can indicate its purity and concentration, which are vital for maintaining quality and safety standards.The versatility of densitometric measurements is evident in their wide-ranging applications. As technology advances, so too do the methods for conducting densitometric analyses. Innovations in instrumentation and data analysis techniques continue to enhance the accuracy and efficiency of these measurements. Researchers are now able to perform densitometric assessments with greater precision, leading to more reliable data and improved outcomes in various studies.In conclusion, the term densitometric (密度测量的) encapsulates a fundamental aspect of scientific inquiry that spans numerous fields. From chemistry to biology and medical imaging, densitometric techniques provide critical insights into the properties and behaviors of materials. As research progresses and methodologies evolve, the significance of densitometric analysis will undoubtedly continue to grow, proving its indispensable role in advancing our understanding of the natural world.

在科学研究和各个学科领域中，术语densitometric（密度测量的）在理解材料及其特性方面发挥着至关重要的作用。密度测量是一种测量物质密度的技术，这可以提供有关其成分和行为的宝贵见解。densitometric分析的重要性可以在多个学科中看到，包括化学、生物学，甚至医学成像。例如，在化学中，densitometric方法常用于确定溶液的浓度。通过测量溶液的密度，科学家可以推断出溶质的含量。这在滴定实验中尤为有用，因为精确的浓度对于准确的结果至关重要。densitometric方法使化学家能够快速评估实验结果，并进行必要的调整，以达到所需的浓度。同样，在生物学领域，densitometric技术被用于分析细胞或生物样本的密度。例如，研究人员可能会使用densitometric测量来评估细胞增殖或凋亡，通过量化培养中的细胞密度。这些信息在药物开发中至关重要，因为了解细胞如何对治疗作出反应可以导致各种疾病治疗的突破。此外，densitometric分析在医学领域也具有重要意义，特别是在成像技术中。X射线成像和计算机断层扫描（CT）等技术依赖于densitometric原理来创建身体内部结构的详细图像。不同组织的密度影响它们吸收或传输X射线的方式，使放射科医生能够区分各种类型的组织并识别潜在的异常。这种densitometric分析的应用不仅有助于诊断，还帮助规划治疗策略。除了这些应用外，densitometric方法还进入了制造业的质量控制流程。食品和饮料、制药以及材料科学等行业采用densitometric技术以确保产品符合特定的密度标准。例如，液体产品的密度可以指示其纯度和浓度，这对维持质量和安全标准至关重要。densitometric测量的多功能性在其广泛的应用中显而易见。随着技术的进步，进行densitometric分析的方法也在不断发展。仪器和数据分析技术的创新继续提高这些测量的准确性和效率。研究人员现在能够更精确地进行densitometric评估，从而导致更可靠的数据和各类研究的改善结果。总之，术语densitometric（密度测量的）概括了科学探究的一个基本方面，涵盖了多个领域。从化学到生物学和医学成像，densitometric技术提供了对材料特性和行为的关键见解。随着研究的进展和方法的演变，densitometric分析的重要性无疑将继续增长，证明其在推动我们理解自然世界中的不可或缺的角色。