In which circaumstanses a high level cratinin person does ct scan?
Best insight from top research papers
A high creatinine level in a person may prompt the need for a CT scan in specific situations. For instance, in trauma cases, CT scans are crucial for evaluating traumatic injuries, determining the need for surgical intervention, and guiding medical management . Additionally, in the context of osteoporosis screening, opportunistic CT scans performed routinely on urinary stone patients have shown diagnostic value in identifying and screening for osteoporosis by measuring vertebral trabecular bone attenuation . Therefore, in scenarios where trauma or osteoporosis is suspected, individuals with elevated creatinine levels may undergo CT scans to assess injuries, monitor progress, or screen for bone density issues.
Answers from top 5 papers
More filters
| Papers (5) | Insight |
|---|---|
3 Citations | Not addressed in the paper. |
| Not addressed in the paper. | |
| Not addressed in the paper. | |
9 Citations | A high-level cratinin person undergoes a CT scan in cases of cranial traumas from gunshot wounds to assess bone and parenchymatous injuries, determine neurosurgical needs, and manage medically. |
| Not addressed in the paper. |
Related Questions
How do different studies define 'time to CT scan' for trauma patients in the emergency department?10 answersThe definition of 'time to CT scan' for trauma patients in the emergency department varies across different studies, reflecting diverse research focuses and methodologies. Some studies define it as the interval from emergency department arrival to the commencement or completion of the CT scan. For instance, the study by Ng et al. determined the time interval from arrival at the emergency department to CT as a critical metric, aiming to assess its impact on in-hospital mortality and hospital length of stay. Similarly, Alrabiah et al. focused on the time from arrival to the completion of pan CT scanning, highlighting the importance of rapid scanning in improving mortality rates in polytrauma patients.
Other research emphasizes the efficiency of the scanning process itself and its subsequent impact on patient care. Weiss et al. and Wood et al. discussed interventions aimed at reducing the CT trauma scan turnaround time, which includes the time from the last image acquisition to the initial report, thereby indirectly addressing the 'time to CT scan' by focusing on overall process efficiency.
In contrast, studies like that of Yamamoto et al. and Ghafil et al. explore the concept of 'time to CT scan' in terms of immediate access to CT scanning upon hospital arrival and the incidence of adverse events during the CT scanning process, respectively, thus providing a broader perspective on the urgency and safety of CT scanning in trauma care.
Moreover, Ashley et al. and Schellenberg et al. investigate the impact of emergency department length of stay and time to first CT Head on hospital mortality, indirectly contributing to the understanding of 'time to CT scan' by examining its implications on patient outcomes.
Lastly, studies by Shubayr et al. and Yoo et al. delve into the utilization patterns of CT scans for trauma patients and the management practices for pediatric patients with severe TBI requiring CT, respectively, offering insights into the decision-making and logistical aspects surrounding 'time to CT scan'.
In summary, 'time to CT scan' is variably defined across studies, ranging from the interval between emergency department arrival and the start or completion of CT scanning, to the efficiency and safety of the scanning process, and its impact on patient outcomes and care practices.
What is ct scan?5 answersA CT scan, or computed tomography scan, is a widely used imaging modality in modern radiology. It provides detailed cross-sectional images of the body, allowing physicians to diagnose various conditions, plan treatments, and monitor therapeutic interventions. CT scans use special X-ray equipment to create images of the internal structure of the body, including organs, blood vessels, and tissues. Unlike general radiography, CT scanners provide three-dimensional volume images acquired from multiple angles, which allows for more information to be generated for diagnosis and management. However, CT scans expose patients to more radiation dose compared to standard radiography. CT scans have numerous clinical indications and are often used in the diagnosis of medical emergencies. They can also be enhanced with the use of contrast media to improve tissue differentiation and characterization.
How can diagnostic reference levels be addressed for computed tomography using artificial intelligence?5 answersDiagnostic reference levels (DRLs) for computed tomography (CT) can be addressed using artificial intelligence (AI) by utilizing machine learning algorithms to analyze dosimetric data and optimize clinical imaging protocols. AI can assist in establishing typical values for radiation doses, estimating effective and organ doses, and comparing them to national and international benchmarks. By considering patient size and using conversion factors, AI can calculate size-specific dose estimates (SSDE) and incorporate them into DRLs for dose optimization. Additionally, AI can help standardize and optimize CT protocols by analyzing data from various studies and national competent authorities, identifying variations in dose descriptor values, and developing strategies for standardization. Continuous monitoring of radiation doses using AI can ensure compliance with DRLs, reduce patient radiation dose, and preserve clinical image quality.
Why were radiographers the first to see ct scan?4 answersRadiographers were the first to see CT scans because they played a vital role in the emergent evaluation of trauma patients and were well versed with the imaging modalities and signs of various pathologies on chest radiographs and computed tomography. CT scans, which allow noninvasive imaging of the true three-dimensional morphology of human organs, were developed by Sir Godfrey Hounsfield in 1967. Hounsfield's computer program performed image reconstruction with impressive accuracy, making it possible to see differences between soft tissues within the body. The story of medical imaging, including CT scans, started with the accidental discovery of X-rays by Wilhelm Conrad Roentgen in 1895. Over the years, medical imaging has undergone great technological advancements, helping physicians create images of the human body to reveal, diagnose, or examine disease. The early developments in ultrasound, CT, and radioisotope imaging were made by a relatively small number of individuals, including Hounsfield, who turned the concept of computerized digital tomography into a reality.
Why radiographer need to take make first reporting in ct brain?5 answersRadiographers are often the first healthcare professionals to view diagnostic images, including CT brain scans, and they are in a unique position to provide expert comment on these images. They can communicate their professional observations directly with the treating clinician in a timely manner, which can significantly influence patient care. However, it is important to note that radiographers may not have the sensitivity required to detect significant abnormalities on CT brain scans, and they cannot be the final diagnostician. Formal training in interpretation of CT brain scans is necessary for radiographers to improve their accuracy in detecting abnormalities. Despite this limitation, radiographers can play an effective screening role in identifying abnormal scans, which can aid in the diagnostic process.
What advantage is there to computed tomography CT scans and magnetic resonance MRI after radiography to show that the patient has no broken bones?5 answers