'Axial' p3 Searchterm 'Axial' found in 17 articles 2 terms [ • ] - 15 definitions [• ] Result Pages : •
(MPR) Multiplanar Reconstruction is a post processing technique for reformatting of a 3D data set at any angle; reconstructing e.g. the axial images into coronal, sagittal and oblique anatomical planes.
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(PII) Pulse inversion imaging (also called phase inversion imaging) is a non-linear imaging method specifically made for enhanced detection of microbubble ultrasound contrast agents. In PII, two pulses are sent in rapid succession into the tissue; the second pulse is a mirror image of the first. The resulting echoes are added at reception. Linear scattering of the two pulses will give two echoes which are inverted copies of each other, and these echoes will therefore cancel out when added. Linear scattering dominates in tissues. Echoes from linear scatterers such as tissue cancel, whereas those from gas microbubbles do not. Non-linear scattering of the two pulses will give two echoes which do not cancel out completely due to different bubble response to positive and negative pressures of equal magnitude. The harmonic components add, and the signal intensity difference between non-linear and linear scatterers is therefore increased. The resulting images show high sensitivity to bubbles at the resolution of a conventional image. In harmonic imaging, the frequency range of the transmitted pulse and the received signal should not overlap, but this restriction is less in pulse inversion imaging since the transmit frequencies are not filtered out, but rather subtracted. Broader transmit and receive bandwidths are therefore allowed, giving shorter pulses and improved axial resolution, hence the alternative term wideband harmonic imaging. Many ultrasound machines offer some form of pulse inversion imaging. See also Pulse Inversion Doppler, Narrow Bandwidth, Dead Zone, Ultrasound Phantom. •
Ultrasound biomicroscopy utilizes high frequency (10 - 50 MHz) diagnostic ultrasound to examine living tissue at a microscopic level and allows to image the skin with extremely high resolution to a depth of 2-3 centimeters. Ultrasound biomicroscopy images provide detailed anatomical information that can lead to better and more accurate treatments and avoid a biopsy. Ultrasound biomicroscopy improves also the spatial resolution of US images of the anterior segment of the eye. US biomicroscopy of the eye operates in the 50 MHz range with a possible axial resolution on the order of 30 μm. In this frequency range, tissue penetration of only approximately 5 mm is attainable. Both continuous wave Doppler and high-frequency pulsed Doppler can be used. See also Ultrasound Imaging Procedures, A-Scan, B-Scan and C-Scan. Further Reading: News & More:
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The ultrasound equipment includes the ultrasound machine, the coaxial cable, the transducer assembly, different modalities to print out and store the ultrasound pictures, ultrasound gel, and a couch for the patients. Often, the ultrasound system is connected with the internal radiology information system which allows the takeover of patient data, and a picture archiving and communication system to store images. See also Ultrasound System Performance. •
Ultrasound machines, widely used in medical imaging, are essential tools in the field of diagnostic ultrasound. These devices utilize high-frequency sound waves to create real-time images of internal body structures. Ultrasound machines consist of several key components that work together to generate diagnostic images.
These include:
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The transducer is a handheld device that emits and receives sound waves. It converts electrical energy into sound waves and captures the returning echoes to create images.
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The control panel houses the interface where the sonographer adjusts imaging parameters such as depth, frequency, and gain. It allows for customization of imaging settings based on the clinical requirements. The transducer pulse controls change the amplitude, frequency and duration of the pulses emitted from the transducer probe.
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The central processing unit (CPU) serves as the brain of the ultrasound machine, processing the acquired data and transforming it into images. It handles complex calculations, image optimization, data storage and contains the electrical power supplies for itself and the transducer probe.
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The display monitor (oscilloscope, tablet, computer monitor, etc.) showcases the real-time ultrasound images produced by the machine. It provides visual feedback to the sonographer, aiding in the interpretation and analysis of anatomical structures. Handheld ultrasound devices and mobile ultrasound probes can be connected wirelessly to a smartphone or tablet via Bluetooth or WiFi. These end device serves then as the ultrasound monitor.
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Data input and measurements are done with the keyboard cursor (trackball). Ultrasound devices used for handheld point of care ultrasound (HPOCUS) are operated via the touch screen of the control panel.
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Images are captured, reviewed, stored and transmitted digitally, using a standard format for digital imaging and communications in medicine (DICOM). Disk storage devices (FDD, HDD, CD, DVD) are outdated, but may be used in older machines to store the acquired images if no picture archiving and communication system (PACS) connection is possible.
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The displayed ultrasound pictures are usually digitally stored in a PACS. The images from portable ultrasound machines can be stored and conveniently managed on the end device itself, the inserted memory card or in the cloud. With a QR scanner, the images can be accessed via the Internet in the cloud. Often there is also the possibility to get a picture of a baby sonography as a printout.
B-mode machines represent the vast majority of machines used in echocardiology, obstetrical scans, abdominal scans, gynecological scans, etc. B-mode ultrasound machines usually produce the sector (or pie segment-shaped) scans. These ultrasound scans require either a mechanical scanner transducer (the transducer moves to produce the sector scan), or a linear array transducer operated as a phased array. Ultrasound machines come in different types, each catering to specific clinical needs. The two primary types are stationary and portable ultrasound machines: •
Stationary units are typically larger in size and are installed in dedicated imaging rooms. These machines offer advanced imaging capabilities and a wide range of specialized features. They are commonly found in hospitals, clinics, and university medical centers where comprehensive imaging services are provided.
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Portable units (see Portable Ultrasound Machine), as the name suggests, are compact and lightweight, designed for on-the-go imaging. These machines are highly versatile and offer excellent mobility, allowing healthcare professionals to bring the ultrasound system directly to the patient's bedside. Portable ultrasound machines are particularly useful in emergency settings, rural healthcare facilities, and point-of-care applications.
See also Handheld Ultrasound, Ultrasound System Performance, Equipment Preparation, Coaxial Cable, and Microbubble Scanner Modification, Environmental Protection and Ultrasound Accessories and Supplies. Further Reading: Basics: News & More:
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