tomographic

简明释义

英[ˌtɒməˈgræfɪk]美[ˌtɒməˈgræfɪk]

adj. 层析成象的

英英释义

单词用法

同义词

反义词

例句

1.Objective to assess the applications of multi-slice spiral computed tomographic angiography (MSCTA) in living related liver transplantation (LRLT) donors.

目的评价多层螺旋ct血管成像(MSCTA)在活体肝移植供体中的临床应用价值。

2.This dissertation has finished basic work for CIT, which is beneficial to further researches on ionospheric tomographic inversion.

本文完成了电离层层析成像技术应用的基础性工作，为进一步深入的研究奠定了良好的基础。

3.Conclusion MRGIH is an important complement to routine MRI images . MRGIH makes it easy to understand MR tomographic images .

结论MRGIH是胃肠道常规MRI断层图像的重要补充，有利于立体全面地理解胃肠道MR断层图像；

4.A reconstruction module (5) reconstructs a motion corrected emission tomographic image from the nuclear decay signals on the basis of the motion correction.

重构模块(5)在运动校正的基础上根据核衰变信号重构经运动校正的发射断层摄影图像。

5.The tomographic approach which basic unit is rectangular block can model and inverse the complex velocity structure.

这种层析反演方法以块体为基本单元，可以模拟和反演复杂速度结构。

6.ObjectiveTo establish and elucidate a feasible method by CT- scanning-based computed tomographic analysis for the volumetric measurement of orbit.

目的探讨采用医学图像分析软件辅助三维CT测量计算眼眶容积的方法及其可靠性。

7.Using the latest tomographic and scanning kit, Laureys found a mind in full working order 23 years after Houben was misdiagnosed.

劳雷斯用最新式的X线断层摄影术和扫描仪发现罗姆的意识处于完全正常的运转状态，而他已被误诊23年了。

8.There were 346 patients with duplicate computed tomographic scans.

有346例反复计算层析扫描。

9.The doctor ordered a tomographic scan to get a detailed view of the patient's brain.

医生要求进行一项断层成像扫描，以详细查看患者的大脑。

10.Advancements in tomographic imaging have greatly improved cancer detection rates.

在断层成像方面的进步大大提高了癌症检测率。

11.Researchers used tomographic imaging to analyze the distribution of pollutants in the environment.

研究人员使用断层成像分析环境中污染物的分布。

12.A tomographic study revealed hidden fractures in the bone structure.

一项断层成像研究揭示了骨骼结构中的隐性骨折。

13.The tomographic technique allows for non-invasive examination of internal organs.

该断层成像技术允许对内部器官进行非侵入性检查。

作文

In the field of medical imaging, the term tomographic refers to a technique that allows for the visualization of internal structures of the body in a detailed manner. This method is crucial for diagnosing various conditions and planning treatments. The most common form of tomographic imaging is computed tomography (CT), which uses X-rays to create cross-sectional images of the body. Unlike traditional X-rays that provide a flat image, CT scans offer a three-dimensional view by compiling multiple tomographic slices. This advantage enables healthcare professionals to see the relationship between different organs and tissues, leading to more accurate diagnoses.The origins of tomographic technology can be traced back to the mid-20th century when researchers began exploring ways to improve imaging techniques. The introduction of the first CT scanner in 1971 revolutionized the medical field, allowing for non-invasive examination of the body’s interior. As technology advanced, so did the capabilities of tomographic imaging. Today, we have various forms of tomographic modalities, including magnetic resonance imaging (MRI) and positron emission tomography (PET), each serving unique purposes in medical diagnostics.One of the key benefits of tomographic imaging is its ability to detect diseases at an early stage. For instance, cancers can often be identified in their initial phases through tomographic scans, significantly increasing the chances of successful treatment. Moreover, these imaging techniques are not limited to oncology; they are also widely used in neurology, cardiology, and orthopedics, among other specialties. The precision offered by tomographic methods allows for targeted interventions, minimizing the risks associated with exploratory surgeries.Despite its advantages, the use of tomographic imaging does come with some concerns. For example, the exposure to radiation during CT scans has raised questions about safety, especially for patients requiring multiple scans. Researchers and medical professionals continue to work on reducing radiation doses while maintaining image quality. Furthermore, the cost of tomographic imaging can be a barrier for some patients, highlighting the need for accessible healthcare solutions.In conclusion, the significance of tomographic imaging in modern medicine cannot be overstated. It has transformed how we understand and treat various health conditions, providing invaluable insights into the human body. As technology continues to evolve, we can expect further advancements in tomographic techniques, enhancing our ability to diagnose and treat diseases more effectively. The future of tomographic imaging holds great promise, paving the way for innovations that could improve patient outcomes and revolutionize healthcare practices worldwide.

在医学成像领域，术语tomographic指的是一种技术，可以详细地可视化身体内部结构。这种方法对于诊断各种疾病和规划治疗至关重要。最常见的tomographic成像形式是计算机断层扫描（CT），它使用X射线创建身体的横截面图像。与提供平面图像的传统X射线不同，CT扫描通过汇编多个tomographic切片提供三维视图。这一优势使医疗专业人员能够看到不同器官和组织之间的关系，从而导致更准确的诊断。tomographic技术的起源可以追溯到20世纪中叶，当时研究人员开始探索改进成像技术的方法。1971年第一台CT扫描仪的推出彻底改变了医学领域，使得非侵入性检查身体内部成为可能。随着技术的进步，tomographic成像的能力也在不断提高。如今，我们有多种形式的tomographic模态，包括磁共振成像（MRI）和正电子发射断层扫描（PET），每种模态在医学诊断中都发挥着独特的作用。tomographic成像的一个主要好处是能够在早期阶段检测疾病。例如，癌症通常可以通过tomographic扫描在初始阶段被识别，从而显著提高成功治疗的机会。此外，这些成像技术不仅限于肿瘤学；它们还广泛应用于神经学、心脏病学和骨科等多个专业领域。tomographic方法提供的精确度允许进行有针对性的干预，最小化与探查性手术相关的风险。尽管有其优势，但使用tomographic成像也带来了一些担忧。例如，CT扫描中的辐射暴露引发了安全性的问题，特别是对于需要多次扫描的患者。研究人员和医疗专业人士继续致力于在保持图像质量的同时降低辐射剂量。此外，tomographic成像的费用可能对一些患者构成障碍，突显了对可及医疗解决方案的需求。总之，tomographic成像在现代医学中的重要性不容小觑。它改变了我们理解和治疗各种健康状况的方式，为人体提供了宝贵的洞察。随着技术的不断发展，我们可以期待tomographic技术的进一步进步，增强我们更有效地诊断和治疗疾病的能力。tomographic成像的未来充满希望，为改善患者结果和革新全球医疗实践铺平了道路。