radiologic

简明释义

英[ˌreɪdiəˈlɒdʒɪk]美[ˌreɪdiəˈlɑdʒɪk]

adj. 应用辐射学的

英英释义

单词用法

同义词

反义词

例句

1.Radiologic Technologists are constantly exposed to various chemical hazards such as sulfur dioxide, glutaraldehyde, and acetic acid. These agents cause asthma.

放射技师经常暴露在各种危险化学品，如二氧化硫，戊二醛，醋酸。这些代理商引起哮喘。

2.The radiologic ASD was diagnosed by plain radiographs and MRI.

通过平片和MRI行ASD的影像学诊断学。

3.The pathologic and physiologic basis of each radiologic features, the mechanisms of high altitude edema and X - ray manifestations were discussed with literature.

最后作者对各种X线征象的病理生理基础，高原性肺水肿形成的机理和X线表现等结合文献作了讨论。

4.According to the X-ray features of the dentigerous cysts in jaws, four radiologic types of these cysts were presented.

本文根据颌骨含牙囊肿X线影像上的差异，将其分成四种类型。

5.Objective To determine the radiologic features of lung complications after single-lung transplantation for end-stage emphysema.

目的探讨肺移植治疗终末期肺病肺气肿围手术期的影像学改变。

6.The final diagnosis depended on clinical, radiologic and laboratory findings and response to therapy.

根据临床表现、检查结果及特异性治疗疗效作最后诊断。

7.The doctor ordered a radiologic 放射学的 examination to assess the patient's condition.

医生要求进行一次放射学的检查以评估病人的情况。

8.In radiologic 放射学的 practice, imaging techniques are crucial for diagnosis.

在放射学的实践中，成像技术对诊断至关重要。

9.The radiologic 放射学的 technologist prepared the patient for an X-ray.

放射学技术员为病人准备了X光检查。

10.Understanding radiologic 放射学的 images is essential for accurate diagnosis.

理解放射学的影像对于准确诊断至关重要。

11.The radiologic 放射学的 findings indicated a possible fracture.

放射学的发现表明可能存在骨折。

作文

The field of medicine has evolved dramatically over the past century, with advancements in technology playing a crucial role in enhancing patient care. One of the most significant developments in this regard is the rise of radiologic imaging techniques. These techniques have transformed the way healthcare professionals diagnose and treat various medical conditions. In this essay, I will explore the importance of radiologic imaging, its applications, and the future prospects of this vital field. Firstly, radiologic imaging encompasses a variety of techniques that utilize radiation to create images of the inside of the body. Common methods include X-rays, computed tomography (CT) scans, magnetic resonance imaging (MRI), and ultrasound. Each of these methods provides unique insights into the human body, allowing doctors to visualize organs, tissues, and bones without invasive procedures. For instance, X-rays are often used to detect fractures, while MRIs are essential for examining soft tissues such as the brain and muscles. The significance of radiologic imaging cannot be overstated. It plays a pivotal role in the early detection of diseases, which can lead to more effective treatment outcomes. For example, mammography, a specific type of radiologic imaging, is crucial for the early diagnosis of breast cancer. Studies have shown that early detection through radiologic imaging significantly increases survival rates. Furthermore, radiologic imaging aids in monitoring the progress of treatments, allowing healthcare providers to make informed decisions about patient care. Moreover, the applications of radiologic imaging extend beyond diagnostics. Interventional radiology, a subspecialty of radiologic medicine, involves minimally invasive procedures guided by imaging techniques. This approach reduces recovery times and minimizes the risks associated with traditional surgery. For instance, interventional radiologists can perform procedures such as biopsies, catheter placements, and even tumor ablations using radiologic guidance, showcasing the versatility and effectiveness of this field. As technology continues to advance, the future of radiologic imaging looks promising. Innovations such as artificial intelligence (AI) and machine learning are beginning to play a role in interpreting radiologic images. These technologies can assist radiologists by providing additional insights and identifying patterns that may not be immediately apparent. As a result, the accuracy and efficiency of diagnoses are expected to improve significantly. In conclusion, radiologic imaging is an indispensable component of modern medicine. Its ability to provide detailed images of the human body has revolutionized the way diseases are diagnosed and treated. The ongoing advancements in this field, including the integration of AI, promise to enhance patient care further. As we look to the future, it is clear that radiologic imaging will continue to play a vital role in healthcare, ultimately improving outcomes for patients worldwide.

医学领域在过去一个世纪中发生了巨大的变化，技术的进步在提升患者护理方面发挥了至关重要的作用。其中最显著的发展之一就是放射学成像技术的兴起。这些技术改变了医疗专业人员诊断和治疗各种医疗状况的方式。在本文中，我将探讨放射学成像的重要性、应用以及这一重要领域的未来前景。 首先，放射学成像包括多种利用辐射创建体内图像的技术。常见的方法包括X光、计算机断层扫描（CT）、磁共振成像（MRI）和超声波。每种方法都提供了对人体独特的洞察，使医生能够在不进行侵入性手术的情况下可视化器官、组织和骨骼。例如，X光通常用于检测骨折，而MRI则是检查大脑和肌肉等软组织的重要工具。 放射学成像的重要性不容小觑。它在早期疾病检测中发挥着关键作用，这可以导致更有效的治疗结果。例如，乳腺摄影是一种特定类型的放射学成像，对于早期诊断乳腺癌至关重要。研究表明，通过放射学成像进行的早期检测显著提高了生存率。此外，放射学成像有助于监测治疗进展，使医疗提供者能够做出关于患者护理的明智决策。 此外，放射学成像的应用超越了诊断。介入放射学是放射学医学的一个子专业，涉及通过成像技术指导的微创手术。这种方法缩短了恢复时间，并减少了与传统手术相关的风险。例如，介入放射科医生可以使用放射学引导进行活检、导管放置甚至肿瘤消融等程序，展示了这一领域的多功能性和有效性。 随着技术的不断进步，放射学成像的未来看起来充满希望。人工智能（AI）和机器学习等创新技术正在开始在解读放射学图像中发挥作用。这些技术可以通过提供额外的见解和识别可能不立即显现的模式来帮助放射科医生。因此，预计诊断的准确性和效率将显著提高。 总之，放射学成像是现代医学不可或缺的组成部分。它提供的人体详细图像彻底改变了疾病的诊断和治疗方式。该领域的持续进步，包括AI的整合，承诺进一步提升患者护理。展望未来，显然放射学成像将在医疗保健中继续发挥至关重要的作用，最终改善全球患者的结果。