Description
The DUS 60 incorporates advanced imaging technologies for best-in-class performance Phase inversion harmonic imaging, multi-beam,and speckle reduction technologies are all standard on the DUS 60, providing increased diagnostic confidence.
Innovative Technologies
Phase-inversion harmonic compound imaging
Improves contrast resolution
Speckle reduction technology
Improves contrast resoltuion while maintaing detail resolution
Multi-beam technology
Synthetic aperture
Dynamic receive focusing
Dynamic frequency scanning
Dynamic apodization
Multi-frequency Transducer Technology
Multiple frequencies increases transducer utility
User-friendly Workflow
Intuitive control panel reduces learning curve
Supported Applications
Abdomen, Obstetrics, Gynecology, Endovaginal, Small Parts, Muculoskeletal, Vascular, Urology, Endorectal, Cardiology, Pediatrics
Compact, Lightweight Design
Two hours of battery-powered operation
12.1″ TFT-LCD monitor
Multiple peripheral ports
Phase Inversion Harmonic Imaging
Harmonic signals are produced as ultrasound waves propagate through the body. Because these signals are produced in the body, they are not influenced by artifact inducing fat near the skin surface. Consequently, an image formed using only the harmonic signal will have less clutter and can be more diagnostic. With phase-inversion harmonics, pairs of ultrasound pulses with opposite phases are transmitted. When the signals received from inverted pulses are added together, the fundamental components are cancelled and only the harmonic signal remains. This creates an image that is pure harmonic with reduction in clutter artifact that degrades the image.
Speckle Reduction Technology
Speckle reduction imaging uses real-time image processing to improve visualization of anatomy and pathology by reducing the speckle noise. Edan’s speckle noise reduction imaging technology uses an advanced multi-scale anisotropic filtering algorithm. This imaging technology is excellent at separating the noise regions from the diagnostic image allowing complex filtering to be performed differently on noise versus true anatomic information thus producing an enhanced image.
Multi-beam Technology
Ultrasound systems use beams that are focused electronically to produce high spatial resolution. Signals from the transducer are delayed and added together in the system to produce a focused ultrasound beam. The same signals can be added together with different delays to produce multiple beams. When this is done, the spatial resolution can be improved without reducing the frame rate or the frame rate can be improved without reducing the resolution. As shown below, with dual beamformation the same receive beams are formed with half the transmit beams, thus doubling the frame rate.
Vascular
Small Parts & Musculoskeletal
Breast Cyst
Baker’s Cyst
Breast Imaging
Testicle
Testicular Doppler
Thyroid – Dual Screen
Thyroid Isthmus Lesions
Transverse Thyroid
OB&GYN
Endovaginal – Sagittal Uterus
Endovaginal – Transverse Uterus
Fibroid Uterus
Fibroid Uterus 2
Third Trimester BPD
Third Trimester – Placenta
Abdomen
Abdominal Aorta – Doppler
Aorta, SMA
Gallbladder, Common Bile Duct
Gallstones
Hepatic Vein Doppler
Right Kidney
Hepatic Veins
Transverse Pancreas
System Transducers
- C361-2
- Applications:
Abdomen, OB/GYN, Urology
Frequencies:
2.5, 3.5, 4.5, H2.5, H2.7 MHz
- L743-2
- Applications:
Small Parts, Vascular, Musculoskeletal, Superficial
Frequencies:
6.5, 7.5, 8.5, H4.5, H4.7 MHz
- C611-2
- Applications:
Cardiology, Pediatrics
Frequencies:
5.5, 6.5, 7.5, H4.5, H4.7 MHz
- L761-2
- Applications:
Small Parts, Vascular, Musculoskeletal, Superficial
Frequencies:
6.5, 7.5, 8.5, H4.5, H4.7 MHz
- E611-2
- Applications:
Endovaginal, OB/GYN
Frequencies:
5.5, 6.5, 7.5, H4.5, H4.7 MHz
- E741-2
- Applications:
Urology
Frequencies:
6.5, 7.5, 8.5, H4.5, H4.7 MHz
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