4DCT: Difference between revisions
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== 4DCT == | |||
'''4DCT''', or four-dimensional computed tomography, is an advanced imaging technique used primarily in the field of [[radiation therapy]] and [[diagnostic radiology]]. It extends the capabilities of traditional [[CT scan|CT scanning]] by incorporating the dimension of time, allowing for the visualization of dynamic processes within the body, such as [[respiration]] or [[cardiac cycle|cardiac motion]]. | |||
== Principles of 4DCT == | |||
The fundamental principle of 4DCT is to acquire multiple CT images over a period of time, capturing the motion of anatomical structures. This is particularly useful in areas where movement can affect the accuracy of imaging, such as the [[thorax]] and [[abdomen]]. By synchronizing image acquisition with the patient's respiratory cycle, 4DCT can provide a series of images that represent different phases of motion. | |||
=== Image Acquisition === | |||
In 4DCT, images are typically acquired using a [[multislice CT scanner]] equipped with software capable of sorting images based on the phase of the motion cycle. The patient may be asked to breathe in a controlled manner, often with the aid of a [[respiratory gating]] device, to ensure consistent and repeatable motion patterns. | |||
=== Data Processing === | |||
Once the images are acquired, they are processed to create a time-resolved series of images. This involves sorting the images into bins corresponding to different phases of the motion cycle. The result is a set of volumetric images that can be viewed sequentially to assess motion. | |||
== Applications of 4DCT == | |||
4DCT is primarily used in the planning and delivery of [[radiation therapy]] for [[cancer]] treatment. It allows for more precise targeting of [[tumors]] by accounting for their movement during the respiratory cycle. This is particularly important in [[lung cancer]] and [[liver cancer]] treatments, where tumor motion can significantly impact the accuracy of radiation delivery. | |||
=== Radiation Therapy Planning === | |||
In radiation therapy, 4DCT helps in creating a more accurate [[treatment plan]] by providing detailed information about tumor motion. This enables the use of techniques such as [[intensity-modulated radiation therapy]] (IMRT) and [[stereotactic body radiation therapy]] (SBRT), which require precise targeting to minimize damage to surrounding healthy tissue. | |||
=== Diagnostic Imaging === | |||
Beyond radiation therapy, 4DCT is also used in diagnostic imaging to assess the function of moving organs. For example, it can be used to evaluate [[diaphragmatic motion]] or to study the dynamics of [[heart valves]]. | |||
== Advantages and Limitations == | |||
=== Advantages === | |||
The primary advantage of 4DCT is its ability to provide detailed information about the motion of anatomical structures, leading to improved accuracy in both diagnosis and treatment. It enhances the ability to visualize and quantify motion, which is critical in many clinical scenarios. | |||
=== Limitations === | |||
Despite its advantages, 4DCT has limitations, including increased [[radiation dose]] due to the need for multiple image acquisitions. Additionally, the complexity of data processing and the need for specialized equipment can limit its availability and use in some clinical settings. | |||
== Related pages == | |||
* [[Computed tomography]] | |||
* [[Radiation therapy]] | |||
* [[Respiratory gating]] | |||
* [[Multislice CT scanner]] | |||
{{Medical imaging}} | |||
{{Radiation therapy}} | |||
[[Category:Medical imaging]] | |||
[[Category:Radiation therapy]] | |||
Latest revision as of 00:41, 19 February 2025
4DCT[edit]
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Spiral 4DCT Lung (Post) -
Spiral 4DCT Lung (Lateral)
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4DCT[edit]
4DCT, or four-dimensional computed tomography, is an advanced imaging technique used primarily in the field of radiation therapy and diagnostic radiology. It extends the capabilities of traditional CT scanning by incorporating the dimension of time, allowing for the visualization of dynamic processes within the body, such as respiration or cardiac motion.
Principles of 4DCT[edit]
The fundamental principle of 4DCT is to acquire multiple CT images over a period of time, capturing the motion of anatomical structures. This is particularly useful in areas where movement can affect the accuracy of imaging, such as the thorax and abdomen. By synchronizing image acquisition with the patient's respiratory cycle, 4DCT can provide a series of images that represent different phases of motion.
Image Acquisition[edit]
In 4DCT, images are typically acquired using a multislice CT scanner equipped with software capable of sorting images based on the phase of the motion cycle. The patient may be asked to breathe in a controlled manner, often with the aid of a respiratory gating device, to ensure consistent and repeatable motion patterns.
Data Processing[edit]
Once the images are acquired, they are processed to create a time-resolved series of images. This involves sorting the images into bins corresponding to different phases of the motion cycle. The result is a set of volumetric images that can be viewed sequentially to assess motion.
Applications of 4DCT[edit]
4DCT is primarily used in the planning and delivery of radiation therapy for cancer treatment. It allows for more precise targeting of tumors by accounting for their movement during the respiratory cycle. This is particularly important in lung cancer and liver cancer treatments, where tumor motion can significantly impact the accuracy of radiation delivery.
Radiation Therapy Planning[edit]
In radiation therapy, 4DCT helps in creating a more accurate treatment plan by providing detailed information about tumor motion. This enables the use of techniques such as intensity-modulated radiation therapy (IMRT) and stereotactic body radiation therapy (SBRT), which require precise targeting to minimize damage to surrounding healthy tissue.
Diagnostic Imaging[edit]
Beyond radiation therapy, 4DCT is also used in diagnostic imaging to assess the function of moving organs. For example, it can be used to evaluate diaphragmatic motion or to study the dynamics of heart valves.
Advantages and Limitations[edit]
Advantages[edit]
The primary advantage of 4DCT is its ability to provide detailed information about the motion of anatomical structures, leading to improved accuracy in both diagnosis and treatment. It enhances the ability to visualize and quantify motion, which is critical in many clinical scenarios.
Limitations[edit]
Despite its advantages, 4DCT has limitations, including increased radiation dose due to the need for multiple image acquisitions. Additionally, the complexity of data processing and the need for specialized equipment can limit its availability and use in some clinical settings.
Related pages[edit]
| Medical imaging | ||||||||||
|---|---|---|---|---|---|---|---|---|---|---|
* Category
|
