Projects per year
Abstract
This Ph.D project addresses image processing in medical ultrasound and
seeks to achieve two major scientific goals: First to develop an understanding
of the most significant factors influencing image quality in medical ultrasound,
and secondly to use this knowledge to develop image processing
methods for enhancing the diagnostic value of medical ultrasound.
The project is an industrial Ph.D project co-sponsored by BK Medical ApS.,
with the commercial goal to improve the image quality of BK Medicals scanners.
Currently BK Medical employ a simple conventional delay-and-sum
beamformer to generate B-mode images. This is a simple and well understood
method that allows dynamic receive focusing for an improved resolution,
the drawback is that only optimal focus is achieved in the transmit focus
point. Synthetic aperture techniques can overcome this drawback, but at
a cost of increased system complexity and computational demands. The development
goal of this project is to implement, Synthetic Aperture Sequential
Beamforming (SASB), a new synthetic aperture (SA) beamforming method.
The benefit of SASB is an improved image quality compared to conventional
beamforming and a reduced system complexity compared to conventional
synthetic aperture techniques. The implementation is evaluated using both
simulations and measurements for technical and clinical evaluations.
During the course of the project three sub-projects were conducted. The first
project were development and implementation of a real-time data acquisition
system. The system were implemented using the commercial available
2202 ProFocus BK Medical ultrasound scanner equipped with a research interface
and a standard PC. The main feature of the system is the possibility
to acquire several seconds of interleaved data, switching between multiple
imaging setups. This makes the system well suited for development of new processing methods and for clinical evaluations, where acquisition of the exact
same scan location for multiple methods is important.
The second project addressed implementation, development and evaluation
of SASB using a convex array transducer. The evaluation were performed as
a three phased clinical trial. In the first phase, the prototype phase, the technical
performance of SASB were evaluated using the ultrasound simulation
software Field II and Beamformation toolbox III (BFT3) and subsequently
evaluated using phantom and in-vivo measurements. The technical performance
were compared to conventional beamforming and gave motivation to
continue to phase two. The second phase evaluated the clinical performance
of abdominal imaging in a pre-clinical trial in comparison with conventional
imaging, and were conducted as a double blinded study. The result of the
pre-clinical trialmotivated for a larger scale clinical trial. Each of the two clinical
trials were performed in collaboration with Copenhagen University Hospital,
Rigshospitalet, and Copenhagen University, Department of Biostatistic.
Evaluations were performed by medical doctors and experts in ultrasound,
using the developed Image Quality assessment program (IQap). The study
concludes that the image quality in terms of spatial resolution, contrast and
unwanted artifacts is statistically better using SASB imaging than conventional
imaging.
The third and final project concerned simulation of the acoustic field for high
quality imaging systems. During the simulation study of SASB, it was noted
that the simulated results did not predict the measured responses with an
appropriate confidence for simulated systemperformance evaluation. Closer
inspection of themeasured transducer characteristics showed a sever time-offlight
phase error, sensitivity deviations, and deviating frequency responses
between elements. Simulations combined with experimentally determined
element pulse echo wavelets, showed that conventional simulation using
identical pulse echo wavelets for all elements is too simplistic to capture the
true performance of the imaging system, and that the simulations can be improved
by including individual pulse echo wavelets for each element. Using
the improved model the accuracy of the simulated response is improved significantly
and is useful for simulated systemevaluation. Itwas further shown
that conventional imaging is less sensitive to phase and sensitivity errors than
SASB imaging. This shows that for simulated performance evaluation a realistic
simulation model is important for a reliable evaluation of new high
quality imaging systems.
Original language | English |
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Place of Publication | Kgs. Lyngby, Denmark |
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Publisher | Technical University of Denmark |
Number of pages | 235 |
Publication status | Published - 2011 |
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Dive into the research topics of 'Image processing in medical ultrasound'. Together they form a unique fingerprint.Projects
- 1 Finished
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Image processing in medical ultrasound
Hemmsen, M. C. (PhD Student), Jensen, J. A. (Main Supervisor), Kortbek, J. (Supervisor), Martins, B. (Supervisor), Hanson, L. G. (Examiner), Jansson, T. (Examiner) & Tortoli, P. (Examiner)
01/08/2008 → 14/12/2011
Project: PhD