Computed Tomography Equipment Techniques PDF

‫جامعة العين‬ ‫كلية التقنيات الصحية والطبية‬ ‫قسم تقنيات االشعة والسونار‬ C o m p u t e d Tomography E q u i p m e n t T e c h n i q u e s Helical/spiral CT Scanners: Requirements for Volume Scanning Dr. Hussein A.Dakhild Ph.D. Medical Imaging Technology ▶ Sixth Generation (Helical or spiral CT) In conventional CT (the 3rd and 4th generation CT scanners), the patient was scanned one slice at a time. The X-ray tube and detectors rotate for 360 degrees or less to scan one slice while the table and patient remain stationary. This slice-by-slice scanning is time-consuming. On the other hand, cables are spooled onto a drum, released during rotation, and respooled during reversal. Scanning, braking, and reversal required at least 8-10 sec of which only 1-2 sec were spent for data acquisition. The result was a poor temporal resolution and long procedure time. Therefore, efforts were made to increase the scanning of larger volumes in less time. This notion led to the development of a technique in which a volume of tissue is scanned by moving the patient continuously through the gantry of the scanner while the X-ray tube and detectors rotate continuously for several rotations. As a result, the X-ray beam traces a path around the patient. The helical or spiral CT development was a revolutionary advancement in CT scanning that finally allowed true 3D image acquisition within a single breath-hold technique. For more clarification, when the examination begins, the x-ray tube rotates continuously while the couch moves the patient through the plane of the rotating x-ray beam, (the table smoothly moves through the rotating gantry). This means that the X-ray tube and detector perform a ‘spiral’ or ‘helical’ movement with respect to the patient, generally at a rate of one revolution per second. In this technique, the data are continuously acquired or collected without pausing while the patient is simultaneously transported at a constant speed through the gantry. For this reason, the duty cycle of the helical scan is improved to nearly 100%, and the volume coverage speed performance can be substantially improved. This technique allows fast and continuous data acquisition from a complete volume. Helical/spiral CT Scanners: Requirements for Volume Scanning Three technological developments were required: o Slip ring technology o high power x-ray tubes o Interpolation algorithms Slip ring technology All generations of CT scanners (except 4th gen.) required winding and unwinding of connection cables causing inter-scan delays. The slip ring was designed to eliminate this. A slip ring is a drum with grooves along which electrical contactor brushes slide. Data are transmitted from detectors via various high-capacity wireless technologies, thus allowing continuous rotation. Eliminating inter-scan delays is made possible by the slip ring technique. A slip ring passes electrical power to the rotating components without fixed connections. It allows the complete elimination of interscan delays except for the time required to move the table to the next slice position. For eg: if scanning and moving the table each take 1s, only 50% of the time is spent acquiring the data. Slip rings are electromechanical devices consisting of circular electrical conductive rings and brushes that transmit electrical energy across a moving interface. All power and control signals from the stationary parts of the scanner system are communicated to the rotating frame through the slip ring. The slip-ring design consists of sets of parallel conductive rings concentric to the gantry axis that connect to the tube, detectors, and control circuits by sliding contactors. These sliding contactors allow the scan frame to rotate continuously with no need to stop between rotations to rewind system cables. This engineering advancement resulted initially from a desire to reduce interscan delay and improve throughput. However, reduced interscan delay increased the thermal demands on the X-ray tube; hence, tubes with much higher thermal capacities were required to withstand continuous operation over multiple rotations. High power x-ray tubes X-ray tubes are subjected to far higher thermal loads in CT than in any other diagnostic X-ray application. In early CT scanners, the power level was low. Since long scan times allowed heat dissipation. Shorter scan times in later versions of CT scanners required high-power x-ray tubes and the use of oil-cooled rotating anodes for efﬁcient thermal dissipation. The introduction of helical CT with continuous scanner rotation placed new demands on X-ray tubes. Several technical advances in component design have been made to achieve these power levels and deal with the problems of the target temperature, heat storage, and heat dissipation. For example, the tube envelope, cathode assembly, and anode assemblies including anode rotation and target design have been redesigned. As scan times have decreased, anode heat capacities have increased by as much as a factor of ﬁve, preventing the need for cooling delays during most clinical procedures, and tubes with capacities of 5–8 million heat units are available. In addition, improvement in the heat dissipation rate (kilo–heat units per minute) has increased the heat storage capacity of modern X-ray tubes. The large heat capacities are achieved with thick graphite backing of target disks, anode diameters of 200 mm or more, improved high-temperature rotor bearings, and metal housings with ceramic insulators. Among other factors. The working life of tubes used to date ranges from 10,000 to 40,000 hours, compared with the 1,000 hours typical of conventional CT tubes. Because many of the engineering changes increased the mass of the tube, much of the design effort was also dedicated to reducing the mass to better withstand increasing gantry rotational rates required by ever-faster scan times.

Computed Tomography Equipment Techniques PDF

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