radiographic
简明释义
英[,reɪdɪəʊ'græfɪk]美[ˌreɪdioʊˈɡræfɪk]
adj. 射线照相术的
英英释义
Relating to or denoting the use of radiation, especially X-rays, to create images of the inside of an object, typically for medical diagnosis. | 与放射线相关的,尤其是指使用X射线来创建物体内部图像,通常用于医学诊断。 |
单词用法
射线照相检验;放射线探伤 | |
放射线照片 |
同义词
| X光 | 医生要求进行X光检查以查看是否有骨折。 | ||
| 放射学的 | Radiological studies are essential for diagnosing many conditions. | 放射学研究对诊断许多疾病至关重要。 | |
| 成像 | Imaging techniques have advanced significantly in recent years. | 成像技术在近年来有了显著进步。 |
反义词
例句
1.Postoperative radiographic features, including fusion status and segmental lordosis, were also examined.
术后放射学特征,包括融合状况和节段前凸也得到研究。
2.The design principle and realization method of a new kind of radiographic welding seam inspection system for steel tube were introduced.
介绍了一种应用于钢管焊接接头检验的射线透视系统的设计原理与实现方法。
3.The structure, principle and character of radiographic real-time imaging system were introduced.
介绍了射线实时成像系统的组成、工作原理及特点。
4.Hospital X-ray machines work by passing an X-ray pulse through a body onto radiographic film.
医院的X光机工作原理是X光射线脉冲穿过人体在射线胶片上感光成像。
5.Study participants were at least 18 years of age. Anyone with clinical or radiographic evidence of acute respiratory infection at baseline was excluded.
研究参与者年龄至少18岁。有急性呼吸道感染的临床或影响学证据者被剔除。
6.Radiographic studies confirmed bone demineralization and osteoporosis commonly seen in patients with RSD.
其放射学检查证实和骨质疏松症等骨骼水质常见于标准偏差。
7.Preoperative and postoperative symptom levels, complications and radiographic findings were recorded and analyzed.
观察术后症状改善及骨折复位情况,分析并发症。
8.We reviewed the medical records and radiographs of 187 patients with 213 amputations who had adequate radiographic follow-up.
我们复习回顾了187名接受了充足的反射影像随访的患者的213例截肢案例的临床记录以及影像学资料。
9.Main Outcome Measurement: Radiographic assessment of fracture healing and clinical assessment of shoulder function.
主要疗效评价指标:骨折愈合的影像学及肩关节功能的临床检查。
10.The dentist took a radiographic 放射性的 image to check for cavities.
牙医拍了一张放射性的图像以检查蛀牙。
11.The radiographic 放射性的 findings indicated a possible infection in the lungs.
该放射性的发现表明肺部可能存在感染。
12.The technician prepared the radiographic 放射性的 equipment before the procedure.
技术员在手术前准备了放射性的设备。
13.A radiographic 放射性的 examination is crucial for diagnosing bone fractures.
进行放射性的检查对诊断骨折至关重要。
14.In oncology, radiographic 放射性的 imaging helps track tumor growth.
在肿瘤学中,放射性的影像有助于追踪肿瘤的生长。
作文
Radiography is a critical field in modern medicine, primarily used for diagnostic purposes. It involves the use of various forms of radiation to create images of the internal structures of the body, allowing healthcare professionals to diagnose and treat medical conditions effectively. One of the most common applications of this technology is in the production of X-rays, which are a type of radiographic (放射学的) imaging technique. These images help doctors visualize bones, organs, and tissues without the need for invasive procedures.The process of obtaining a radiographic (放射学的) image begins with the patient being positioned in front of an X-ray machine. The machine emits a controlled amount of radiation that passes through the body and is captured on a special film or digital sensor. The varying densities of different tissues in the body absorb the radiation at different rates, resulting in a clear contrast on the image. For instance, bones appear white on an X-ray because they are denser and absorb more radiation, while softer tissues, like muscles and organs, appear darker.Beyond X-rays, the term radiographic (放射学的) also encompasses other imaging modalities such as computed tomography (CT) scans and magnetic resonance imaging (MRI). Each of these techniques has its own specific uses and advantages. CT scans, for example, provide cross-sectional images of the body and are particularly useful for diagnosing complex fractures or internal injuries. MRI, on the other hand, uses powerful magnets and radio waves to produce detailed images of soft tissues, making it invaluable for neurological and musculoskeletal assessments.In addition to diagnostics, radiographic (放射学的) imaging plays a significant role in treatment planning and monitoring. For instance, oncologists rely heavily on radiographic (放射学的) imaging to evaluate the size and location of tumors. This information is crucial when determining the appropriate course of action, whether it be surgery, radiation therapy, or chemotherapy. Moreover, follow-up radiographic (放射学的) studies are essential to assess the effectiveness of treatment and make necessary adjustments.The advancements in radiographic (放射学的) technology have significantly improved patient outcomes. Digital radiography, for example, has enhanced image quality and reduced radiation exposure. This technology allows for immediate viewing of images, facilitating quicker diagnoses and treatment decisions. Furthermore, the integration of artificial intelligence in radiographic (放射学的) imaging is an exciting development, as it can assist radiologists in identifying abnormalities and improving accuracy.Despite the benefits, it is important to consider the risks associated with radiographic (放射学的) imaging. The exposure to ionizing radiation, although generally low, can pose risks, especially with repeated examinations. Therefore, healthcare providers must weigh the potential benefits against the risks and ensure that radiographic (放射学的) exams are conducted judiciously.In conclusion, radiographic (放射学的) imaging is an indispensable tool in contemporary medicine. Its ability to provide detailed images of the body's internal structures enables accurate diagnosis and effective treatment planning. As technology continues to evolve, the future of radiographic (放射学的) imaging looks promising, with the potential for even greater advancements in patient care. Understanding the principles and applications of radiographic (放射学的) imaging is essential for both healthcare professionals and patients alike, as it represents a crucial intersection of science and medicine.
放射摄影是现代医学中的一个关键领域,主要用于诊断目的。它涉及使用各种形式的辐射来创建身体内部结构的图像,使医疗专业人员能够有效地诊断和治疗医疗状况。这项技术最常见的应用之一是在X光片的制作中,X光片是一种放射学的成像技术。这些图像帮助医生在不需要侵入性程序的情况下可视化骨骼、器官和组织。获得放射学的图像的过程始于患者被定位在X光机前。该机器发出控制量的辐射,穿过身体并被特殊胶卷或数字传感器捕获。体内不同组织的不同密度以不同的速度吸收辐射,从而在图像上产生清晰的对比。例如,骨骼在X光片上显得白色,因为它们更密集,吸收更多的辐射,而较软的组织,如肌肉和器官,则显得更暗。除了X光,术语放射学的还包括其他成像方式,如计算机断层扫描(CT)和磁共振成像(MRI)。每种技术都有其特定的用途和优势。例如,CT扫描提供身体的横截面图像,对于诊断复杂骨折或内部损伤特别有用。而MRI则利用强大的磁场和无线电波生成软组织的详细图像,使其在神经系统和肌肉骨骼评估中不可或缺。除了诊断之外,放射学的成像在治疗计划和监测中也发挥着重要作用。例如,肿瘤科医生在评估肿瘤的大小和位置时严重依赖于放射学的成像。这些信息对于确定合适的治疗方案至关重要,无论是手术、放疗还是化疗。此外,后续的放射学的检查对于评估治疗效果和进行必要的调整至关重要。放射学的技术的进步显著改善了患者的结果。例如,数字放射摄影提高了图像质量并减少了辐射暴露。这项技术允许即时查看图像,促进更快的诊断和治疗决策。此外,人工智能在放射学的成像中的整合是一项令人兴奋的发展,因为它可以帮助放射科医生识别异常并提高准确性。尽管有诸多好处,但考虑到与放射学的成像相关的风险也是很重要的。尽管辐射暴露通常较低,但在重复检查时可能会带来风险。因此,医疗提供者必须权衡潜在的好处与风险,确保放射学的检查的合理进行。总之,放射学的成像是当代医学中不可或缺的工具。它提供了身体内部结构的详细图像,使得准确的诊断和有效的治疗计划成为可能。随着技术的不断发展,放射学的成像的未来看起来充满希望,有可能在患者护理方面取得更大的进步。理解放射学的成像的原理和应用对于医疗专业人员和患者来说都是至关重要的,因为它代表了科学与医学的关键交汇点。
