Language
Country/Area
No result found
What you don't know about phosphor plate imaging technology: Why can it break the boundaries of traditional X-rays?
As technology advances at a rapid pace, medical imaging technology also continues to advance. Among the various imaging techniques, Computed Radiography (CR) has gradually attracted attention because it can provide a faster diagnostic method than traditional X-rays. How does phosphor plate imaging technology work? What advantages allow it to break the boundaries of traditional X-rays?
Phosphor plate imaging technology is gradually replacing traditional X-ray files with its advantages of instant image preview and automated processing.
The rise of digital radiology
Digital radiology is a technology that utilizes photographic plates to capture data directly, which is transferred to a computer system immediately during the patient examination without the need for intermediate film processing. Advantages of this technology includetime efficiency and reduced radiation exposure to patients, while providing image contrast similar to traditional radiology.
Among them, flat panel detectors (FPDs) are the most common direct digital detectors. FPDs can be divided into indirect FPDs and direct FPDs. Indirect FPDs use sodium fluoride or calcium titanium fluoride to convert X-rays into visible light, which is then converted into digital signals by a photosensor. Direct FPDs use amorphous selenium, which can directly convert X-ray photons into electrical charges, providing more accurate detection performance.
The revolution in digital radiology lies not only in the advancement of technology, but also in how it changes the way medical diagnosis is done, allowing doctors to make decisions faster.
How phosphor plate imaging works
Phosphor plate imaging technology uses an imaging plate that contains a phosphorescent material that can be stimulated by light. After exposure to X-rays, a latent image is formed. It uses alaser scanning method to read the latent image point by point and digitize it. . One of the advantages of this technology is that it can be used without changing existing equipment, meaning that medical institutions do not need to undergo costly equipment upgrades.
In addition, this technology is not limited to the medical field, but is also widely used in industrial testing, especially in non-destructive testing of aviation and electronic materials. Digital radiology technology provides results in real time, which is critical to safeguarding the integrity of the material.
The popularity of this real-time imaging technology has fundamentally changed the way medical and industrial testing is done, bringing more possibilities.
Advantages and Challenges of Phosphor Panels
Although phosphor plate imaging technology has many advantages, it is not without its challenges. First, using this technology requires additional scanning equipment and maintenance costs. In addition, although it can replace the traditional film system, it still has high technical requirements for operators in some cases. With the advancement of technology, many medical institutions are gradually adopting digital radiology to improve the efficiency of diagnosis. The emergence of this new technology not only makes medical services more convenient, but also provides patients with safer examination options.Future Outlook
The future of digital radiology and phosphor plate imaging technology shows great potential for development. With the advancement of digital processing technology, the reduction of costs and the continuous improvement of image quality, these new technologies are expected to be more deeply integrated into medicine and industry in the future.With the cumulative advancement of technology, the application of digital radiology will no longer be limited to the medical field, but may also expand to a wider range of industrial applications in the future.
Phosphor plate imaging technology is undoubtedly breaking the boundaries of traditional X-rays and will continue to promote the evolution of medical and industrial imaging technology in the future. What unprecedented breakthroughs will we see in this digital revolution?
